1. Field of the Invention
This invention relates generally to a building protective and aesthetic siding that is used to cover the exterior of a building and, specifically, to a building siding that includes horizontal planks that are interlocked together on top and bottom and that are installed from the top of a building wall in a downward direction. The invention includes the use of an adaptor strip that can be adhesively affixed to existing fiber cement siding planks or comparable material while providing for top down interlocking of the planks for durability and protection from wind and rain.
2. Description of Related Art
Many buildings, residential dwellings and office buildings, use building siding on the exterior of the building for protecting the building from the elements and for aesthetic purposes. Typical building siding is constructed of a plurality of elongated, horizontal panels, planks, or strips that are typically overlapped from the wall bottom upwardly, with each next piece added that overlaps the piece below it. Such overlapping panels are used to protect the building from rain, solar and wind damage. The siding used on many residential and commercial buildings for the exterior is typically made of wooden planks that are overlapped, typically from the wall bottom upwardly. Plastic, polyvinyl chloride (PVC), and aluminum sheets have also been used. Many of these materials are also sloped to aesthetically look like wood planks that are overlapped, one on top of the other giving each plank a slight incline instead of a substantially flat surface.
One of the problems with conventional siding that is constructed with panels or planks from the wall bottom up, i.e. each horizontal plank being covered by one on top of it, is that high winds can lift a plank reducing the siding durability.
The siding described herein adds durability and protection from wind and rain because the siding planks are placed on the building from the top down. Each of the individual horizontal planks are more securely held in place because of the top and bottom interlock connections.
The present invention can be used with existing planks such as fiber cement siding by utilization of an adaptor strip that is adhesively affixed to each existing fiber cement siding plank that allows the fiber cement siding plank to be interlocked from the top down for greatly improving durability and protection from wind and rain. Each plank and adaptor strip is fastened to the building exterior wall along the base area of the adaptor strip.
Exterior building siding which may be constructed of several types of materials including aluminum, polyvinyl chloride (PVC), wood, steel, concrete, hard foam or other synthetic materials having essentially two components which include: (1) a top starting strip that is affixed to the building at a selected upper beginning point of a building wall or structure and (2) a plurality of planks of the same or variable lengths that are affixed to the starting strip and to the building itself, usually to vertical studs forming the building exterior wall.
The starting strip is the uppermost horizontal strip and has an inverted “J-shaped” cross section. The strip body inverted “J-shaped” cross sectional configuration provides for a substantially upside down deep recess or groove that is disposed vertically and is tapered to receive the upper “L-shaped” lip portion of the first horizontal mounting plank. The starting strip may have a plurality of small circular recessed dimples that provide visual alignment for fasteners such as screws, nails or staples to be driven through the strip in such a manner that the head of the screw or nail is flush or countersunk below the level of the exterior surface. The strip can also be attached by glue. After the top starting strip has been fastened to the selected upper position on the building exterior wall, the horizontal siding planks are attached sequentially downwardly from the starting strip. The planks may be rectangular in shape of the same or different lengths that can be cut to make each horizontal row equal to the building wall width. Each plank has a cross section that includes a top tapered “L-shaped” area that is upright and a bottom “J-shaped” area that is inverted forming a groove. In one embodiment, the upper length of the “L-shaped” area leg of each plank is longer that the bottom portion of the “J-shaped” leg as described below.
The planks used in the siding are joined and interlocked vertically on top and bottom in horizontal rows, and are arranged in end to end abutments. The planks can be manufactured in various dimensions in terms of width or height and thickness and can be of different lengths depending on the nature of the building to be covered with siding. Each plank can be cut in length and width to fit any wall size.
The starting strip inverted “J-shaped” cross section area has a continuous groove from end to end that may be tapered and is sized to snuggly fit with the upper “L-shaped” projection of the top edge of the siding plank. Thus, when the first plank is inserted snuggly into the starting strip, there is a tight fit between both the starting strip groove and the first plank projection.
At the bottom of the every plank, there is an inverted “J-shaped” area with a groove similar to the groove inverted “J-shaped” groove in the starting strip. This plank lower groove is interlocked with the top edge of the next horizontal plank added downwardly.
The starting strip and each plank are attached to the building exterior wall surface or studs by nails, screws, staples or glue. The heads of the nail and screw fasteners may be countersunk in pre-formed recessed areas. Assembly of an exterior wall of siding begins with the attachment of the starting strip at a location that denotes the horizontal upper starting line of the siding. The starting strip is nailed, screwed, stapled or glued to the building horizontally.
A first series of planks are horizontally pushed into firm engagement in the starting strip groove and each plank is nailed, screwed, stapled or glued into place along the bottom area of each plank forming the first row of planks.
Each additional row of planks is engaged to the fastened planks downwardly, one row at a time. The fasteners securing the previous planks are covered by the next row of planks.
The planks forming the very bottom row may have to be cut longitudinally for a perfect fit to reduce their height to conform to the remaining space to be covered. These planks may be glued to the building exterior wall or studs.
In one embodiment, the inside (back) surfaces of the starting strip and all planks are flat and form a flat plane flush with the building wall or studs.
In an alternate embodiment, the back wall surface of each plank and the starting strip can include one or more vertical recessed channels (curved or rectangular in shape) that form vertical moisture or fluid conduits that allow drainage of moisture that accumulates on the outside exterior surface of the building but on the inside of the planks to dissipate moisture in the vertical channels by gravity.
Also in an alternate embodiment, the plank end faces that are placed side by side for each plank, instead of being flush, could include a groove flange overlap such that the outer surface edge of one plank overlaps the inner side edge of the adjacent planks. Between each overlap structure a small vertical space can be made as a moisture channel.
In a further alternate embodiment, the starting strip and planks can be installed onto the roof of a building as well as the soffits of a building. In this alternate embodiment, the starting strip and planks are installed in the same top-down manner as described when used for siding.
Using the present invention as described, it is noted how secure each of the individual planks are, both at the top and at the bottom, which greatly increases its durability against harsh weather elements such as wind and rain for greater strength and longer preservation.
In the preferred embodiment, the siding is comprised of a conventional elongated plank made of fiber cement or other material, that is adhesively attached or bonded to an elongated adaptor strip which allows fiber cement conventional planks of siding to be securely trap locked above and below against a building horizontally from the top of the building wall downwardly.
The adaptor strip is an elongated strip, which may be extruded, milled or molded from various materials, that includes a front flat face in its upper portion, a mid panel support on its rear face to prevent or reduce the cement board damage due to flying debris, extra material for increase strength near a recessed area that runs the entire length of the adaptor strip to reduce the volume of material used and a lower extended nailing or fastener flange.
The adaptor strip can be affixed with adhesive to the fiber cement board at the factory. The siding unit is comprised of the conventional fiber cement board or other material and is bonded to the adaptor strip that provides horizontal planks attached vertically for interlocking at top and bottom of each fiber cement panel or plank. The siding unit has a bottom or base groove that is large enough to receive the top flat edge of a fiber cement board that is trap locked between the adaptor strip and the base of an above fiber cement board that is already attached to a building exterior along its base area.
Optionally, within the base groove, a resilient elongated moisture barrier member is placed at the top surface of the inverted groove. The moisture stop could be longitudinally disposed throughout the base groove of the entire plank and adaptor strip. As each cement fiber board is interlocked below to the previously attached groove plank, the top edge engages and self-aligns at the stopping point in the inverted groove with or without the moisture stop. The moisture stop reduces moisture from reaching the exterior building wall being covered or the siding fasteners from the front surface.
Also in the preferred embodiment with the adaptor strip, the back face surfaces of the adaptor strip include narrow moisture transmission grooves that are substantially diagonally and vertically positioned but can be angled. The adaptor strip back surface moisture grooves are used in conjunction with an adaptor strip horizontal recess in the adaptor strip that reduces the volume of material used in the device. The adaptor strip mid panel support back face also includes a series of moisture transmission grooves substantially positioned diagonally and vertically.
The longitudinal recess in the adaptor strip may be trapezoidally shaped in cross section (as opposed to rectangular) so that moisture will not accumulate due to gravity allowing moisture to run down the recess wall surface between moisture transmission grooves.
Thus, each siding panel horizontally attached to an exterior building wall is mounted from the top down, interlocking each lower panel is comprised of a fiber cement board or other material that can be made in a conventional rectangular shape with an adaptor strip adhesively bonded to the back side of the fiber board. The siding unit can be interlocked and fastened along its extended base area with the adaptor back wall face extending below the front of the fiber board to allow for fasteners such as nails, screws or staples to be fastened along the base to a building wall. The adaptor strip can have a large longitudinal recess specifically to reduce the volume of material used in the entire siding unit while, at the same time, not sacrificing strength.
It is an object of this invention to provide a building exterior siding that is affixed from the top down with an interlock cross sectional pattern between adjacent horizontal panels to give the siding more strength and durability in use.
It is another object of this invention to provide an improved exterior panel that can be easily assembled and mounted on the exterior of a building in a top down progression for increased strength and durability of the siding.
It is a primary objective of this invention to provide siding that can be made from fiber cement or other conventional material and bonded to an adaptor strip that allows for rigid interlock from a top down construction of the siding for fastening along the base of each siding unit and may provide for moisture transmission grooves along the interface between the adaptor strip and the building exterior wall to which it is attached.
In accordance with these and other objects which will become apparent hereinafter, the instant invention will now be described with particular reference to the accompanying drawings.
Referring now to the drawings and, particularly,
It is further contemplated that each starting strip 12 may additionally have a plurality of shallow vertical grooves located on the flat back wall. These grooves will extend from the top of the flat back wall to the bottom of the flat back wall.
Referring now to
It is further contemplated that each siding plank 14 may additionally have a plurality of shallow vertical grooves located on the side of the plank 14 which will share a planar relationship with the flat back wall of the starting strip 12. These grooves will extend from the top edge to the bottom edge of the plank 14.
Looking at
Referring now to
Looking at
Looking at
The back surfaces 12a and 14d are flat. The siding planks 14 and starting strip 12 can be made in various widths and thicknesses and lengths and from many different materials including mixed fibers, wood, concrete, steel, aluminum, plastics, polymers, foam or other blended or natural or man-made composite materials. The siding can function not only as a protective outer layer on a building protecting the building against wind, moisture, rain and solar energy, but also acts as an insulation for heat or cold. Overall, the siding provides greater uplift protection from stronger than average wind and moisture intrusion that results in a reduction of costly repairs and replacements to the building.
Referring to
As shown in
As an alternative embodiment, referring now to
Each starting strip 200 may additionally have a plurality of shallow vertical grooves located on the flat back wall. These grooves will extend from the bottom of the flat back wall to the top of the flat back wall.
Referring now to
Each siding plank 210 may additionally have a plurality of shallow vertical grooves located on the back side of the plank 210d which will share a planar relationship with the flat back wall of the starting strip 200. These grooves will extend from the top edge to the bottom edge of the plank 210.
As an alternative embodiment, referring now to
The preferred embodiment of the invention is shown in
Referring now to
The starter strip 310 includes a groove 310a that receives a fiber cement board 302 upper edge in an interlocking fashion. The starting strip in
Engaged to the starting strip is a cement board 302 that has been adhesively bonded to the adaptor strip 304. The adaptor strip 304 has upper and lower flat back surfaces that engage the wall of the building 316. The exterior wall of the building 316 could also be a stud or flat surface material. Each of the adaptor strips is attached to the building wall 316 with fasteners such as screw, nail, adhesive or staples 312. Each siding unit made up of the fiber cement board 302 and the adaptor strip 304 is interlocked from the top down in a trap lock fashion. The bottom front surface area of each adaptor strip is long enough to overlap beyond the bottom groove such that the fastener 312 can be attached. To further explain, the bottom front surface and wall of the adaptor strip extends beyond the very bottom edge of the fiber cement board 302 which forms the interlocking groove along the base of the entire siding unit being attached. There is sufficient front surface area from the adaptor strip to allow fasteners 312 to be attached along the base of the siding unit. There is also area within the inverted groove for the sealing member 306 which is resilient and water resistant such as an artificial or natural rubber strip or other material that can be sufficiently resilient to allow the board 302 to be suitably engaged with the above siding unit groove to prevent moisture and rain from reaching the inside of the unit.
Referring now to
In addition, the adaptor strip 304 includes an extended lower base 304b that is a rectangular extension extending beyond the bottom surface 302c of the fiber cement board 302. There is sufficient front surface area exposed of the adaptor strip 304b to allow attachment of screws, nails, staples or adhesive 312 along the bottom area of the adaptor strip thus attaching the entire siding unit along the bottom edge horizontally across the exterior building wall being covered. There is also volume in the groove formed between the adaptor strip 304 and the cement board 302 to receive a sealing resilient moisture barrier 306 that engages the very top surface 302b of the fiber cement board 302 when interlocked.
A very important feature of the adaptor strip and siding unit is a large trapezoidal longitudinal recess 304c along the back wall that extends the entire length of adaptor strip 304. The purpose of the trapezoidal recess 304c is to reduce mass and volume. The adaptor strip can be extruded and by having a substantial recess that runs at least between from top to bottom a quarter and a half along the entire body length of the adaptor strip and half the thickness, a large amount of mass of material and volume is reduced in the extrusion process, reducing material costs without sacrificing strength. Also having trapezoidal shaped surfaces allows for moisture to drop by gravity along the passage walls 304c between moisture transmission grooves 308 which are grooves on the mid panel support 304a and on surface 304b.
In
The relative lengths of the fiber cement board or any other conventional board, including wood or any other material 302, are essentially the same lengths as the extruded adaptor strip when the two elements are joined together. Once permanently joined the siding unit 300 can be cut with a saw just like any other type of board or plank. The height and relative height between the front board 302, regardless of the material, and its thickness and the height of the adaptor strip are important to be in the proper locations for achieving the interlocking and trap lock characteristics of the siding unit itself. As shown in
The adaptor strip can be used with standard planks constructed of various materials using known manufacturing process such as extrusion, molding or milling without compromising the material or design integrity. The adaptor strip mounts and bonds to existing materials by the adhesive back which also provides a method of concealing the fasteners so that they are not exposed to the elements or visible. Using the adaptor strip in conjunction with a standard plank of material, the siding planks can then be engaged continuously at their top and bottom edges beginning with a starting strip in a top down fashion. This provides a self aligning installation. By using a foam or rubberized weather strip bead, water intrusion is reduced or eliminated. The adaptor strip can be made of any material but is preferably extruded from a polymer type material.
Based on studies done, it is believed that the adaptor strip can provide a design mode that is equal to two and a half times greater in strength than that of a standard plank before the use of the adaptor strip.
The overall siding unit shown allows for much quicker installation which also may reduce construction costs.
Referring now to
The modified adaptor strip 402 is shown in its working position in
The adaptor strip front flat upper wall surface attached to said cement fiber board is not parallel to said adaptor strip as shown in
Referring now to
With the planks 502, which could be extruded, milled or molded, additional recessed areas 502a, 502c and 502e run parallel longitudinally along the back wall of each plank to reduce the mass or volume of material used. In addition, the flat back surfaces provide for support platforms 502b, 502d and 502aa. These flat support platforms are disposed on each side of the recesses to prevent damage to the plank from flying debris if the plank were not supported properly.
The optional alternate embodiment of the invention shows the use of a resilient, artificial or natural rubber moisture stop 504 which is mounted in the base groove of each plank and which, because of its resilience, can be compressed when the lower plank is inserted into the bottom groove of the adjacent plank for interlocking. As shown in
The instant invention has been shown and described herein in what is considered to be the most practical and preferred embodiment. It is recognized, however, that departures may be made therefrom within the scope of the invention and that obvious modifications will occur to a person skilled in the art.
Number | Name | Date | Kind |
---|---|---|---|
492736 | Shull | Feb 1893 | A |
720893 | Charlebois | Feb 1903 | A |
1931709 | Schaffert | Oct 1933 | A |
1986739 | Mille | Jan 1935 | A |
2110579 | Robinson | Mar 1938 | A |
2241642 | McCauley | May 1941 | A |
2831218 | Stark | Apr 1958 | A |
3046700 | Davenport | Jul 1962 | A |
3173229 | Weber | Mar 1965 | A |
3217453 | Medow | Nov 1965 | A |
3228164 | Ettore | Jan 1966 | A |
3261136 | Abner et al. | Jul 1966 | A |
4065899 | Kirkhuff | Jan 1978 | A |
4096679 | Naz | Jun 1978 | A |
4672789 | Fortier | Jun 1987 | A |
4718214 | Waggoner | Jan 1988 | A |
5016415 | Kellis | May 1991 | A |
5475960 | Lindal | Dec 1995 | A |
5502940 | Fifield | Apr 1996 | A |
5634314 | Champagne | Jun 1997 | A |
5657585 | Zaccagni | Aug 1997 | A |
5675955 | Champagne | Oct 1997 | A |
5711117 | Zaccagni et al. | Jan 1998 | A |
6226947 | Bado et al. | May 2001 | B1 |
7713615 | Black et al. | May 2010 | B2 |
7762040 | Wilson et al. | Jul 2010 | B2 |
20030014936 | Watanabe | Jan 2003 | A1 |
20050166529 | Rodolofo et al. | Aug 2005 | A1 |
20070130871 | Johnson et al. | Jun 2007 | A1 |
20080155928 | Weiss | Jul 2008 | A1 |
20090313934 | Carlson | Dec 2009 | A1 |
Number | Date | Country | |
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20090007517 A1 | Jan 2009 | US |
Number | Date | Country | |
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Parent | 11774247 | Jul 2007 | US |
Child | 12194979 | US | |
Parent | 12018416 | Jan 2008 | US |
Child | 11774247 | US |