The present application relates to panel assemblies. In particular, the present application relates to aluminum interlocking panel assemblies.
Panel assemblies are aesthetic assemblies that can provide structural support, protection from the environment, delineate walkways, and in some cases, provide acoustic variation. Panel assemblies are typically affixed to the sides of buildings, installed near doors, connected together with canopies, and form free-standing structures. When affixed to the sides of a building, panel assemblies are useful to decorate the building. However, conventional panel assemblies often are monochromatic, or do not easily give the appearance of real wood.
Conventional panel assemblies are assembled and connected together, often with adhesive, on-site, making them immobile without significant damage to the building to which they are attached or to the individual panel beams of the assembly. After connecting the panel assembly together, the assembly is sanded and then painted or finished on-site, often requiring caustic chemicals to be used on-site.
Conventional panel assemblies often have exposed cuts from the various dimensions of the individual parts. Often, the irregular sized/shaped parts that result from cutting cannot be used, resulting significant waste. Gaps between cuts are often created by butting joints of the individual parts together. Over time, these gaps expand, creating aesthetic and structural deficiencies in the panel assembly. General wear and tear, for example from hail, rain, foot traffic, etc., can cause individual panels to become disconnected, making them loose relative to the remainder of the panels. Repairing loose paneling is difficult, time-consuming, and expensive.
Often, panel assemblies are made of wood or other materials susceptible to mold, mildew, bacteria, odors, or other contaminants. Once contaminated, the panel assembly must be sanded, refinished, and/or removed, in order to nullify the effects of the contamination.
Thus, conventional panel assemblies are limited by their ability to provide desired aesthetic appeal, be securely fabricated, be finished at a manufacturing facility, be moved in one-piece to the jobsite, and/or provide contaminant-resistive properties. Additionally, large panel assemblies are heavy, making them difficult to hoist and install due to their weight and size. Furthermore, the connected panel assemblies cannot be resized at the jobsite once the assembly is connected together, greatly limiting on-site adjustments. Thus, there exists significant room for improvement in the art for overcoming these and other shortcomings of conventional systems and methods for panel assemblies.
Although the aforementioned methods of constructing panel assemblies represent great strides in the area of paneling, many shortcomings remain.
The novel features believed characteristic of the present application are set forth in the appended claims. However, the invention itself, as well as a preferred mode of use, and further objectives and advantages thereof, will best be understood by reference to the following detailed description when read in conjunction with the accompanying drawings, wherein:
Referring to
Preferably, attachment member 26a and inserting member 26b are flanges, but could also be formed as tabs, tongues, or posts. Either a groove of receiving end 23 receives the inserting member of another panel support, or inserting end 27 inserts into the receiving end of another panel support (see
Preferably, inserting member 26b is removably encompassed about by a portion of another panel of the panel assembly. Alternatively, the portion of the other panel is in-part removably encompassed about by inserting member 26b.
In a preferred embodiment, the shape and configuration of receiving end 23 comprises and inverted F-shape, having an inverted C-shape integrally attached to the inverted F-shape. The shape and configuration of inserting end 27 comprises an inverted C-shape, a J-shape, or sideways U-shape, having another C-shape integrally attached to it.
In a preferred embodiment, attachment member 26a is about 10-14% of the entire width of a panel support 20 without a centered support, and about 6-8% of the entire width of a panel support 20 that has a centered support. Inserting member 26b is about 3-7% of the entire width a panel support 20 without a centered support, and about 2-3% of the entire width of the panel beam with a centered support. A recess between the two flanges of receiving end 23 is approximately twice as wide/thick as the wall thickness of panel support 20. A groove or recess in inserting end 27 is approximately 30-40% wider/thicker than the wall thickness of panel support 20.
Preferably, panel support 20 has curved support members 24a, 24b that have openings 30a, 30b. Curved support members 24a, 24b function or are formed as screw bosses, clip members, structural reinforcing supports, and/or provide additional advantages as described below. Preferably, openings 30a, 30b have approximately identical dimensions. In at least one embodiment, openings in curved member 24b of inserting end 27 is about 6% larger than opening 30a in receiving end 23. Other dimensions and dimensional variations are encompassed by the Present Application.
In a preferred embodiment, the sidewalls connected to body portion 25 are slightly angled at a similar or identical angle to form a groove for assembly with another panel beam. For example, one sidewall may have an angle of from about 15-30 degrees relative to a vertical plane extending through the C-shape of curved support member 24a (see, receiving end 123 of
In a preferred embodiment, at least one of ends 24, 27 of panel support 20 includes another linear flange or attachment tab parallel to and paired with the first linear flange. For example, receiving end 23 has an attachment tab 31 parallel to and paired with first linear flange 26a. It is noted that receiving end 23 of panel support 20 is configured to receive a linear flange of an inserting end 27 of a second panel beam (not shown in
In at least one embodiment, panel support 20 includes an optional centered support 29 that is approximately centered along body 25 of panel support 20. Although centered support 29 is depicted as a component formed in the unitary structure of body 25, alternatively, centered support 29 may be formed by folding, attachment, such as welding, or by other means known in the art. Centered support 29 is optional depending on multiple factors, including but not limited to, one or more dimensions of panel support 20, an intended use for panel support 20, and a desired aesthetic preference. For example, panel support 20 may vary in width, with some embodiments being from three to four inches in width, while other embodiments may be from six to eight inches in width. Centered support 29 may be included in the larger dimensioned embodiments, but optionally excluded from the smaller dimensioned embodiments. It is noted that additional dimensional variations not specifically mentioned are encompassed by the Present Application.
Preferably, panel support 20 is an extruded aluminum beam, formed using a die print that has a shape therein that is the same shape as face 50 of the panel support 20. For example, a die is first formed, then a heated aluminum billet is pushed through the die having the shape of face 50 to form panel support 20. Other steps in beam formation may include but is not limited to, quenching, mechanical treatment, and aging.
Referring now to
Center portion 129 includes one or more grooves 169. Alternatively, centered portion 129 includes folds, bends, creases, or other structural enhancements to modify the strength of the beam. In at least one embodiment, the top and bottom surfaces of center portion 129 of support 120 are smooth. It is important to note that ends 123 and 127 depicted in
Referring now to
Referring now to
Panel assembly 200 can be cut to length in a shop or in at the installation site because the extruded members are shipped unassembled from the shop to the installation site. Furthermore, because the extruded members can be cut at the site before assembly the parts for the panel assembly can be adjusted at the site. For example, if the measured length of the panel assembly needed to be reduced, the panel beams can be precisely cut to reduce the length of the panel assembly. Conventional welded panel assemblies require a large amount of work to adjust the dimensions of the panel assembly. Since the panel assembly is assembled at the installation site, the amount of equipment to hoist the panel assembly up bit by bit is less than the amount of hoisting equipment needed for conventional welded panel assemblies.
It should be apparent that panel assembly 200 does not have fasteners viewable from a front elevation view of the panel assembly. The hidden fasteners of panel assembly 200 increase the aesthetic appeal of the assembly. Furthermore, the hidden fasteners require less finishing work and over time any corrosion due to a reaction between the fasteners and the extruded members is hidden from view.
Referring now also to
Referring now also to
Clip member 224 preferably includes one or more flanges 526 and a spring bias created by the material of clip member 224, the spaced-apart structure, a proximity of one or more walls and flanges 526, and/or combinations thereof. Clip member 224 also includes an opening 530 within a tab 531 for receiving the stud of a fastener. Tab 531 extends away from the body of clip member 224. Clip member 224 facilitates the alignment and fastening of panel beams 220b and 220c to each other and to substrate 210. Opening 530 may be configured as circular, elongated, elliptical, rectangular, slots, holes, or combinations thereof. Openings 530 are strategically placed to hide fasteners used to secure the panel assembly 200 from visual sight relative to the exterior of the panel assembly 200.
Panel 220 of the multiple rectilinear panels is preferably made of aluminum, an aluminum alloy, or an anodized aluminum, where, during the anodizing, the aluminum is treated with a dye or a color pigment to provide color to the aluminum. For example, a dye may give the aluminum a wood-like appearance. Alternatively, panel 220 is made of a sheet metal material, such as steel, tin, or combinations of metals and/or metal alloys and incorporates an external coloration and/or pigmentation. It is noted that the lightweight materials are preferred, as they can be thin enough and still provide sufficient strength to be as durable as wood, and yet add less weight to the assembly than a wooden beam. For example, beams having wall thicknesses as low as from about 0.05 inches to 0.07 inches are used in the panel assembly 200. Beams having larger wall thicknesses are also encompassed by the present application.
Because folded/bent panel beams can be formed and cut at the job-sit, or in the shop, according to any desired dimension, there is a significant reduction in waste from forming panel assemblies from the panel beams. For example, a panel beam can be formed to the precise length needed, and together with the clip members and attachment ends of the panel beams, there is no need to cut the beams into wasteful segments.
In at least one embodiment, panel beam 220 is formed from sheet metal as a single unitary component, including spaced-apart hems. Likewise, clip members 224 are also formed as a single unitary component.
Panel beams 220b and 220c are depicted having ends 226b and 226c welded with welds 226d and 226e, providing additional support to the respective panel beams. Alternatively, the flanges corresponding to the edges 226b and 226c are unattached, meaning the edges 226b and 226c are folded downward or bent at the appropriate angle and do not include a weld or other attachment means, relying on the force of the bend to maintain the desired shape of the panel beams 220b and 220c.
Referring now also to
Attachment flange 631 includes one or more openings 630 for attachment to panel support substrate 210. Although the shape of openings 630 are depicted as circular, other openings having different shapes, sizes, and dimensions are encompassed in the present application. For example, openings 630 may be circular to receive threaded stud 652 of a fastener, or elongated to receive the head of a fastener that is inserted then turned to lock the fastener in place. Openings 630 may be configured as slots to receive a hook or a tab mounted to, or extending from, panel support substrate 210, or to allow for adjustment. At least one opening 630 has an adjacent dimension 628 relative to a longitudinal surface of panel beam 220a and/or relative to the width of attachment tab 627. For example, adjacent dimension 628 may be equivalent to the width of insertion tab 627, such that the insertion tab of another panel beam (not shown) does not rest on a fastener inserted into opening 630.
Spaced-apart hem 624 is made when attachment tab 631 is folded or bent towards top surface 621 of panel beam 220a. After the folding or bending, bottom surface 611 rests parallel to a surface of the panel support substrate 210. Within spaced-apart hem 624, top surface 621 of panel beam 220a is situated at an angle offset from the surface of panel support substrate 210.
Multiple fasteners 626 of the panel assembly 200 are configured to have self-securing, self-sealing, and/or water-resistive properties. For example, fasteners 626 may include a self-tapping screw head 652 and a water-sealing O-ring or gasket 654, such as a nylon or neoprene washer. Fasteners 626 drill into one or more layers of sheet metal to attach a panel beam to a surface of panel support substrate 210. It is important to note that the use of water-sealing fasteners, the non-corrosive material composition, and the overlapping or layering configuration of attachment tab 631 with a second attachment flange of another panel beam provides water-resistant properties to panel assembly 200. It is also important to note that although fasteners 626 are depicted as below bottom surface 611, fasteners 626 are preferably inserted from above top surface 621 of attachment tab 631.
Referring now also to
Referring now to
In an alternative embodiment, border support beams 240, or a portion thereof, are replaced by, or used in-part together with, end caps that insert into portions of the extruded panel support 220. For example, the end caps may include pegs, dowels, or studs that insert vertically into clip members 24 having openings 30 similar to those depicted in
It is important to note that although support beams 240a, 240b are depicted as tube-like beams having 45° angles, this depiction is only for simplification in explaining one attachment mechanism of support beams 240a, 240b. Other embodiments of support beams 240 include individual beams having edges and/or spaced-apart hems to interconnect with edges and spaced apart hems at the latitudinal edges of panel beams 220.
As shown in
Referring now to
Referring now to
Referring now also to
Referring now to
Referring now to
Referring now to
Referring now also to
It is important to note that at least
Because extruded panel beams can be formed and cut at the job-sit, or in the shop, according to any desired dimension, there is a significant reduction in waste from forming panel assemblies from the panel beams. For example, a panel beam can be formed to the precise length needed, and together with screw bosses, and attachment ends of the panel beams, there is no need to cut the beams into wasteful segments. Screw bosses at the ends of panel beams enable joining two different panel beams through the use of threaded studs inserted between two different screw bosses of the two different beams to form a near-seamless, very long panel beam.
Referring now to
Referring now to
Referring now also to
It is important to note that end cap 2258 can be interchanged with a second similarly shaped, or differently shaped end cap. The interchanging also enables changing the aesthetics, such as by making the color of the end cap the same or different than the beams of the panel assembly. A width dimension of the exposed surface of the end caps also make joints and panel beam ends cleaner, with reduced gaps and reduced waste.
Referring now also to
At Step 2402, a method 2400 starts by providing computer software, hardware, folding machines, raw materials, and other resources necessary for the formation of the panel assembly.
Step 2404 includes generating a panel design, which includes assigning a beam number or count to each beam. For example, a column number and beam number may be assigned. Preferably, the panel design is generated using computer software, such as a CAD program. Step 2404 includes determining longitudinal and latitudinal dimensions of beams. These determinations are made based on federal regulations, industry guidelines, or municipal code if the panel assembly is used for structural support. Alternatively, these determinations are made based on an aesthetic appeal. Step 2404 further includes ensuring a seam of a column of panel beams in the design does not align at least with a seam in the iteratively next column of panel beams. Alternatively, step 2404 includes ensuring seams do align, based on aesthetic preferences, panel design, or designer/manufacturer preference.
Step 2406 includes providing a panel support substrate that will support each of the multiple panel beams used in the design generated in Step 2404. The support substrate is also configured to attach each panel beam. Step 2406 includes determining an appropriate material composition for the panel support substrate. For example, wood may be used if fasteners include wood screws and the panel assembly will remain indoors or will be substantially covered (i.e., when it is used together with a canopy). Alternatively, cinder block, brick, or aluminum or another lightweight, rigid material such as carbon fiber, titanium, or steel tubing, is provided as the panel support substrate.
Step 2408 includes forming the panel beams. Step 2408 includes an initial determination 2409 as to whether or not the panel beams need coloring. At Step 2409 the determination is made that the beams need coloring. As the preferred material composition is aluminum, Step 2408 may include an additional coloring process 2410. For example, Step 2410 may include anodizing the aluminum used to form the beam panels and then dyeing or adding pigment during the anodizing process. Alternatively, an alloy is added during the beam formation, which may add a desired characteristic, such as color, strength, ductility, or combinations thereof, to the panel beam. In at least one embodiment, other coloring techniques are used, such as a topical application, such as enamel, or an electrolytic coloring (EC) process. It is noted that the border support beams are colored the same, or different than, the panel beams depending on the design or aesthetic appeal desired.
At Step 2411, the determination is made that the beams are formed using extrusion. The process then jumps to Step 2432.
Returning to Step 2409, the determination is made that no coloring is necessary. Returning to Step 2411, the determination is made that the beams are not formed using extrusion. For example, the panel beams are made of aluminum sheet metal using a folding or bending process.
Referring now to
Step 2412 includes calibrating a machine to perform the plurality of folds or bends. This may include entering machine parameters, including but not limited to, entering and/or determining a material thickness, a bend allowance, a moment of bending, a floated radius, and a die opening. The calibration may include making initial bends to create a flat blank, adjusting measurements and parameters while making the blank, and then recording finalized measurements and parameters. It is noted that portions of Step 2412 may be performed using machine learning, artificial intelligence, and predictive analysis. Such techniques may make using different materials, material thicknesses, and design geometries faster, easier, and less costly.
Step 2414 includes determining whether the most complicated feature of the panel beam is being formed. For example, step 2414 includes determining whether a hem, which has the highest number of folds, will be made.
At Step 2416 it is determined that a hem is not being formed. Step 2416 includes determining whether the second most complicated feature is being formed. For example, a flange may require only two folds.
At Step 2416 it is determined that a flange is not being formed. Step 2418 includes determining whether the least complicated feature is being formed. For example, an edge or a corner may require only a single fold.
At Step 2418 it is determined that a corner is being formed. Thus, Step 2420 includes performing a fold by moving the folding bar in a first direction, D1, which for 90-degree corners, results in a bending angle of 90 degrees and an opening angle of 90 degrees. A wiper tool may be used to form the corner.
Returning to Step 2418, it is determined that an edge is being formed. Thus Step 2420 includes performing a fold by moving the folding bar in second direction, D2, or the first direction, D1, depending on the design, previous fold, and the type of folding machine being used. A panel bender, folding tool, or rotary tool may be used to form edges.
Returning to Step 2418, the determination is made that an edge is not being formed. Step 2422 includes determining whether another feature or shape will be formed. Step 2424 includes following instructions, such as pre-programmed or written instructions, for forming the other shape and/or feature.
Returning to Step 2414, the determination is again made that a hem is not being formed. Returning to Step 2416, the determination is mad that a flange is being formed. Since a flange requires two folds, the first in one direction, D2, and the second in an opposite direction, D1, the method proceeds to Step 2426 and then returns to Step 2420 again.
Returning to Step 2414, the determination is made that a hem is being formed. Because a hem requires at least three folds, with a first fold being in a first direction, D2, the second being in substantially the same direction, D2, and the third being in an opposite direction, D1, the method proceeds to Step 2428, returns to Step 2426, and then returns to Step 2420.
Returning to Step 2422, the determination is made that another shape and/or feature is not being formed, or that there is no instructions for forming the other shape and/or feature. At Step 2430, the sub-process ends.
Returning again to
Referring now to
Step 2436 includes determining the beam number or count assigned at Step 2404, when the design is generated.
At Step 2436, a portion of the first beam of the design is positioned on the panel support substrate. For example, a longitudinal edge or flange to the panel support substrate may be slid onto the panel support substrate into place.
At Step 2438, the first portion of the first beam is secured. For example, the longitudinal edge may be secured using fasteners. Preferably, in the first iteration of the assembly cycle, threaded fasteners secure an attachment tab to the panel support substrate. In a subsequent iteration of the assembly cycle, fastener flanges are snapped or interlocked into place with a receiving end of a previously positioned panel support.
At Step 2440, the determination is made that the beam is the end beam for its respective column. For example, the single beam 220a depicted in
At Step 2442, the determination is made that the column number and beam number associated with the panel beam do not indicate it is the last beam in the panel assembly design.
At Step 2444, both the column number and the beam number for the placement instructions, machine, or manufacturer, are incremented. The sub-process then cycles back through Steps 2436 and 2438, placing a longitudinal edge of another beam, sliding the next beam of the next column into place, and securing the longitudinal edge of the next beam of the next column.
Returning to Step 2440, alternatively in the first phase of the cycle, the determination is made that the beam, based on its associated beam number and column number, is not the last beam in the column. For example, in
At Step 2448, the latitudinal edge of the subsequent beam (e.g., beam 920b) of the column is slid against the latitudinal edge of the previous beam of the column (e.g., beam 920a). At Step 2450, both edges abut one another as the latitudinal edge of the second beam is further slid into place and secured. For example, Step 2448 may include positioning a clip member along the latitudinal edge, and Step 2450 includes securing the latitudinal edge within the clip member. In at least one embodiment, Step 2450 includes securing the clip member. For example, clip member 224 of
At Step 2438, a second portion of the subsequent beam is secured into place. For example, the longitudinal edge may be snapped into place using a fastening flange of the subsequent beam and a receiving end of a previous beam.
Returning again to Step 2440, the determination is made that the beam is the last beam in the column. Again, this determination is made using the associated beam number.
At Step 2442, the determination is made that the column number and beam number associated with the subsequent beam (e.g., beam 920b) does not indicate it is the last beam in the panel assembly design.
At Step 2444, both the column number and the beam number for the placement instructions, machine, or manufacturer, are incremented. The sub-process then cycles back through Steps 2436 and 2438, placing a longitudinal edge of another beam by abutting it within the receiving end (e.g., spaced-apart hem) of the previous column of panel beams (e.g., beams 920a and 920b), sliding the first beam of the second column into place, positioning the longitudinal edge in collinear alignment with the longitudinal edge of the first column of beam(s), and securing the longitudinal edge of the first beam of the second column in the receiving end of the previous column. These cycles continue until the last beam number and/or last column number are obtained.
Returning to Step 2452, the determination is made that the beam is the last or end beam in the design. At Step 2452, the border supports are positioned around the panel assembly.
At Step 2454, the sub-process of placing panel beams on the panel support substrate ends. This termination point triggers the next step in method 2400.
Returning again to
It is important to note that steps may be performed in a different order than indicated above and the resulting method and/or process still be encompassed in the Present Application. For example, in some embodiments, Step 2411 may occur before Step 2409, as the coloring process in Step 2410 may depend on an initial determination that an extrusion process will be used to form the panel beams.
It is apparent that an invention with significant advantages has been described and illustrated. Although the present application is shown in a limited number of forms, it is not limited to just these forms, but is amenable to various changes and modifications without departing from the spirit thereof.
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