The present invention relates to a system and method for finishing fenestration openings.
General contractors engaged in the construction of a commercial or residential building are responsible for scheduling various subcontractors to complete their assigned tasks in a timely manner. When a certain subcontractor's work is delayed for some reason, further delays may be caused for other subcontractors whose tasks are dependent on the first subcontractor. For instance, plumbing and electrical work must be completed before interior drywall can be hung; likewise painting and finishing cannot proceed until the drywall is hung. To the extent that a job can be planned so that as few subcontractors are dependent on the completion of each other's work as possible, a smoother job with fewer delays is likely to result.
While better scheduling and planning on the part of the general contractor can reduce these bottlenecks, some are unavoidable due to requirements imposed by current building materials. For example, fenestration openings are unfinished openings in the side of a building which will ultimately receive a window or door assembly. Currently, windows are delivered by the manufacturer having a frame which is attached to the framing members of the fenestration opening. Until this frame is installed, the finishing crews, which apply the exterior finish such as plastering to the building as well as the interior drywall crews, cannot complete their work. Accordingly, delays in shipment and installation of the windows and frames lead to significant problems in work scheduling for the building as a whole, which can potentially cause an entire job to fall behind schedule.
A need exists for a system and method which reduces the need for a high degree of coordination between subcontractors. With such a system and method, the burden on the window and door manufacturers to deliver on a tight schedule is reduced, and the general contractor regains a degree of control over his schedule without worrying about being held up by his custom window and door suppliers not delivering on time.
Accordingly, a fenestration cap system is provided as a separate piece from the frame of the window. The fenestration cap can be installed prior to the delivery of the widows and accompanying frames, and allows interior and exterior finishing to be completed without having to install the window and door systems. This allows more time for custom window and door orders to be filled by the supplier without holding up progress in other areas of the job. The waiting for the actual windows to arrive and be installed is no longer one of the critical paths of the job schedule, and may be completed at the convenience of the contractor.
This system is compatible with the frames of major door and window suppliers, and gives consumers the flexibility to choose the windows and doors that best fit their specific needs without being forced to make a selection due to manufacturer lead times. Furthermore, the present system is easy to install, and can be done by tradesmen with minimal training. The inclusion in certain embodiments of the present invention of flanges and stops reduces the need for careful measuring and placement of finishing materials such as drywall sheeting.
The fenestration cap system allows window and door openings to be made ready to receive their corresponding accessories, while at the same time being easily made weatherproof in the absence of these accessories with the addition of a simple piece of panel or sheeting.
Additional benefits are provided if accessories such as windows and doors are installed after finishing crews complete their work, which may include the application of plaster to the outside of the storefront, or the installation of drywall along the inside. In this case, The window and door systems installed within the fenestration cap do not need to be masked off by the finishing crews, and they are not in danger of being damaged by the finishing crews.
In one embodiment of the present fenestration cap system, future window replacement can be achieved by simply removing the window fasteners holding the window and possibly the frame within the fenestration cap, cutting out the perimeter window sealant, and sliding the window out leaving the integrity of the structural and building substrates in a finished undisturbed state.
In an exemplary embodiment, a window sill comprises a structural base having a first side and a second side, a fenestration cap attached to the structural base, a window frame mounted on the fenestration cap, and finish elements applied to the structural base and adjacent to the fenestration cap. The window frame may be removed from the fenestration cap without disturbing the finish elements.
In an alternative embodiment, a fenestration cap comprises a first surface for receiving a window and a second surface attached to the first surface for attachment to a fenestration opening. The window is separably detachable from the first surface and the fenestration opening is detachable from the second surface. Furthermore, detachability of the window from the first surface is independent of detachability of the fenestration opening from the second surface.
A method of installing a window in a window opening comprises providing a window opening and preparing the window opening for receiving a fenestration cap, installing a fenestration cap by placement within and attachment to the window opening in a primary step, and installing a window within the window opening by placement within and attachment to the fenestration cap in a secondary step.
Before any embodiment of the invention is explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and arrangements of components set forth in the following description, or illustrated in the drawings. The invention is capable of alternative embodiments and of being practiced or being carried out in various ways. Also, it is to be understood that the terminology used herein is for the purpose of illustrative description and should not be regarded as limiting.
The present fenestration cap was designed to systematically coordinate and weatherproof fenestration openings before the installation of commercial or residential windows or doors. In one embodiment, the fenestration cap is a permanent fixtures in the building in which it is installed. The present cap allows for plastering and installation of interior drywall to be completed after installation of the fenestration cap itself, all of which may be completed at the leisure of a general contractor before delivery of the windows and associated frames is even taken. As such, a delay in such delivery will not unnecessarily inconvenience the contractor and delay the job; plasterers and finishing crews no longer need to wait for the delivery of windows to a job site to complete their portions of the build.
Once the windows and frames do arrive, they can be installed separately by attachment to the fenestration cap with sheet metal screws or other appropriate fastening means. Furthermore, if the window panes themselves ever need to be replaced, the frames in which they are mounted can be easily detached from the fenestration cap without the need to remove the cap itself. Formerly, the unitary frame in which windows were mounted and which was attached directly to the window opening necessitated a complete tear-out of the window opening to replace the window itself. As such, windows and doors are made independent and easily replaceable building components rather than permanent parts of the building structure.
Such an arrangement is known by those skilled in the art to be prone to leakage. The sill can 150, together with a sill can filler 155 and a sill can stop 160 forms a frame assembly which secures a window 170. One or more top load gaskets 171 as well as a setting block 172 may also be used with this assembly to further secure, cushion and waterproof the window 170.
With the embodiment shown, finish work on the window opening may only be completed once the window 170 and frame arrives. As such, the scheduling problems discussed above are common with this prior art embodiment. Furthermore, if the window 170 and frame needed to be changed, any plastering and drywall used to finish the window opening would have to be removed at that time.
As discussed above, finishing crews are responsible for the installation of the plaster 436 and drywall sheeting 438, but these elements cannot be installed until a terminal point is provided for them to be finished against. In the prior art, this terminal point was provided by the sill can or frame of the window itself. However, this caused the previously mentioned problems of delays in construction while the finishing crews waited for the window and associated sill can and frame to be delivered.
In the embodiment shown in
Similarly, in the shown exemplary embodiment, the fenestration cap 400 includes a base 415, a top side 417 generally parallel to the base, as well as a first support 419 and a second support 421 between the base and the top side. The key 446 has at least a portion that extends perpendicularly from a side 411 defining a flashing 412, and along the same plane as the top side 471. The exemplary embodiment fenestration cap also includes a drywall channel 445 provided as a guide to receive a piece of drywall sheeting 438 such as standard ⅝″ sheetrock. This channel aids an unskilled laborer in the installation of interior drywall, plaster or paneling. The built in receiving and self-aligning channel creates a level fit for the installation of interior finish materials. Accordingly, the sheeting running from a corner bead 439 to the fenestration cap 400 can be quickly and accurately installed in a level position without the time consuming process of shimming or manual adjustment of the sheeting necessary with prior art systems.
In the embodiment of the present invention shown in
In one embodiment of the present invention, the fenestration cap 400 is installed in the window opening using one or more wood screws 430 through the vertical flashing 412 and a mounting flange 415 to secure the fenestration cap 400 to the underlying structure of the window opening, namely the wood framing members 435 and/or the plywood sheeting 437. A vertical flashing 412 may be provided allowing the fenestration cap 400 to be attached to the plywood sheeting 437. A self healing membrane 434 may be placed between the vertical flashing 412 and the plywood sheeting 437 to provide further waterproofing for the underlying structure of the window opening. The self healing membrane 434 may be in one embodiment a continuous waterproof self healing rubberized membrane is manufactured from polypropylene. The vertical flashing 412 also provides additional waterproofing to the finished window assembly by providing a water barrier to any water which infiltrates behind the plaster 436. The fenestration cap 400 may be attached by its interior side with one or more additional wood screws 430 to the wood framing members 435.
An expansion cavity 433 may be provided between the fenestration cap 400 and the wood framing members 435 which may contain a foam strip, 3/16″ thick in one exemplary embodiment to act as a shock absorber in the event of thermal or other expansion of the underlying members or seismic movement.
It will be understood by one skilled in the art that the inventive concepts of the invention described herein are not limited to a fenestration cap for use only with the specific materials discussed above, such as plaster and drywall for instance. In lieu of plaster for example, a variety of siding materials can be used to finished the exterior of the storefront assembly shown in
The fenestration cap 400 shown in
Furthermore, the width of the fenestration cap may be designed in various widths to fit various windows and window openings. The present invention is designed to work with window systems from multiple companies. As is known to one skilled in the art, the width of a commercial window is customarily measured with reference to its mullion width. These widths come in standard sizes including 2, 3, 4, 4.5 and 6 inches in width, among others. It is envisioned that a fenestration cap may be designed to match each of these standard window widths, although one skilled in the art will understand that a fenestration cap according to the present invention can be made to match any width window.
The fenestration cap 400 may be assembled in the contractor's shop or on the job site itself into a custom system for any size window opening by cutting stock lengths of the fenestration cap 400 at forty-five degree angles (or any other set of complementary angles). These lengths can then be attached to each other using fasteners passing through the integral screw races 405 of adjacent lengths of fenestration cap 400. For an aluminum fenestration cap, stainless steel sheet metal screws can be used as fasteners.
If the fenestration cap 400 is assembled in the contractor's shop and transported to the job site, a blank made of styrofoam or other material may be inserted into the center of the fenestration cap assembly to stiffen it for transport. This blank may be secured within the assembly using double-sided tape. Furthermore, after the fenestration cap is installed in the window opening, a blank secured within the fenestration cap 400 assembly using double sided tape may be also used to weatherproof the capped window opening in lieu of the window itself. Taped plastic sheeting may also be used for this purpose. In any event, fenestration cap assembly provides and easy base from which to tape or otherwise weatherproof a window opening prior to the installation of the window assembly.
The sill can 450 shown in
In one embodiment of the present invention, at some point after the fenestration cap 400 itself has been installed in the window opening, the sill can 450, having a window 470 therein, may be lifted onto the length of fenestration cap 400 shown in
If the fenestration cap 400 is used with a frame such as the sill can 450 and related components shown in
A water dam 411 may be provided at the interior side of the caulk bead 452 as a further moisture barrier in the event that water is able to infiltrate through to the interior side of the caulk bead 452. The water dam 411 also provides a stop allowing for easy installation of the window and sill can 450. Once the fenestration cap 400 is in place in a window opening, an unskilled laborer would easily be able to install the sill can 450 and related components to provide a finished storefront by lifting the window assembly up and into the opening within the fenestration cap assembly, placing the interior edge of the sill can 450 firmly against the water dam 411. As such, no measuring is required for the installation of the window assembly itself when the fenestration cap 400 has been used to frame the window opening ahead of time.
Furthermore, even if despite all the precautions built into the design of the fenestration cap 400, water is able fully infiltrate the joint in the area of the caulk bead 452 and pass over the water dam 411, the fenestration cap 400 fully spans the width of the window opening in which it is placed so that any water which does manage to flow over the fenestration cap 400 is directed over, rather than into, the wall on which the fenestration cap 400 rests.
The fenestration cap 400 may be provided with a thermal break 410 to reduce the transfer of heat through the fenestration cap 400 to help meet energy efficiency building requirements such as California's. Title 24 requirements. Accordingly, an insulation material is formed in a cavity of the fenestration cap 400. This insulation material has sufficient strength such that after it is formed in the cavity, a portion of the fenestration cap 400 can be removed in the vicinity of the insulation such that the fenestration cap 400 becomes two thermally separate pieces joined only by the insulation. This helps to substantially thermally isolate the interior from the exterior of the finished storefront by preventing heat transmission through the fenestration cap 800.
The fenestration cap 400 has the additional advantage that over prior art systems in that it can span doorway openings in a storefront and need not be trimmed to the jamb of a doorway. With the addition of a separate threshold unit, the section fenestration cap 400, spanning the bottom of a doorway, presents a finished appearance. Accordingly, a single length or series of lengths of the fenestration cap 400 can be made to span the base of an entire storefront serving as both a sill of a window and a door threshold.
As in the previous embodiment, the fenestration cap 500 is attached to the wood framing members 535 and plywood sheeting 537 using a series of wood screws 530. The fenestration cap 500 is provided with a drywall channel 545 and plaster key 546 designed to receive drywall sheeting 538 and plaster 536. A spacer 509 may be provided to support the drywall sheeting 538 in the area of a corner bead 539.
As in the previous figures, the fenestration cap 800 is provided with a plaster key 846 to facilitate the easy application of the plaster 836, and a drywall channel 845 to facilitate the installation of the drywall sheeting 838. The fenestration cap 800 is secured to the wood framing members 835 and the plywood sheeting 837 using one or more wood screws 830. Furthermore, the fenestration cap 800 is provided with a thermal break 810, which may be supplemented with the creation of a saw cut 896 in the fenestration cap 800 to substantially thermally isolate the interior from the exterior of the finished storefront, preventing heat transmission through the fenestration cap 800.
As in
The gap between the sill can 1050 and the fenestration cap 1000 is sealed with a caulk bead 1052. As in other embodiments, a gap of set height 1053 is provided as part of the caulk bead 1052 to match industry standard warranty requirements. A water dam 1011 is provided at the interior side of the caulk bead 1052 as a moisture barrier in the event that water is able to infiltrate through to the interior side of the caulk bead 1052, and to provide a stop for easy installation of the sill can 1050.
The embodiment of
The preceding description has been presented with reference to some embodiments of the invention. Workers skilled in the art and technology to which this invention pertains will appreciate that alterations and changes in the described structure may be practiced without meaningful departing from the principal, spirit and scope of this invention. Accordingly, the foregoing description should not be read as pertaining only to the precise structures and methods described and illustrated in the accompanying drawings, but rather should be read consistent with and as support to the following claims which are to have their fullest and fair scope. For instance,
This application is a continuation of application Ser. No. 13/225,131, filed on Sep. 2, 2011, which is a divisional of application Ser. No. 11/027,860, filed on Dec. 30, 2004, issued on Sep. 27, 2011 as U.S. Pat. No. 8,024,898, the contents of which are fully incorporated herein by reference.
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Number | Date | Country | |
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20130160395 A1 | Jun 2013 | US |
Number | Date | Country | |
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Parent | 11027860 | Dec 2004 | US |
Child | 13225131 | US |
Number | Date | Country | |
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Parent | 13225131 | Sep 2011 | US |
Child | 13773275 | US |