The invention is related to an insulated fiber cement siding.
A new category of lap siding, made from fiber cement or composite wood materials, has been introduced into the residential and light commercial siding market during the past ten or more years. It has replaced a large portion of the wafer board siding market, which has been devastated by huge warranty claims and lawsuits resulting from delamination and surface irregularity problems.
Fiber cement siding has a number of excellent attributes which are derived from its fiber cement base. Painted fiber cement looks and feels like wood. It is strong and has good impact resistance and it will not rot. It has a Class 1(A) fire rating and requires less frequent painting than wood siding. It will withstand termite attacks. Similarly composite wood siding has many advantages.
Fiber cement is available in at least 16 different faces that range in exposures from 4 inches to 10.75 inches. The panels are approximately 5/16 inch thick and are generally 12 feet in length. They are packaged for shipment and storage in units that weigh roughly 5,000 pounds.
Fiber cement panels are much heavier than wood and are hard to cut requiring diamond tipped saw blades or a mechanical shear. Composite wood siding can also be difficult to work with. For example, a standard 12 foot length of the most popular 8¼ inch fiber cement lap siding weighs 20.6 pounds per piece. Moreover, installers report that it is both difficult and time consuming to install. Fiber cement lap siding panels, as well as wood composite siding panels, are installed starting at the bottom of a wall. The first course is positioned with a starter strip and is then blind nailed in the 1¼ inch high overlap area at the top of the panel (see
Current fiber cement lap siding has a very shallow 5/16 inch shadow line. The shadow line, in the case of this siding, is dictated by the 5/16 inch base material thickness. In recent years, to satisfy customer demand for the impressive appearance that is afforded by more attractive and dramatic shadow lines virtually all residential siding manufacturers have gradually increased their shadow lines from ½ inch and ⅝ inch to ¾ inch and 1 inch.
Disclosed herein are embodiments of foam backing panels for use with lap siding and configured for mounting on a building. One such embodiment of the foam backing panel comprises a rear face configured to contact the building, a front face configured for attachment to the lap siding, alignment means for aligning the lap siding relative to the building, means for providing a shadow line, opposing vertical side edges, a top face extending between a top edge of the front face and rear face and a bottom face extending between a bottom edge of the front face and rear face.
Also disclosed herein are embodiments of siding panel assemblies. One such assembly comprises the foam backing panel described above, with the alignment means comprising alignment ribs extending a width of the front face, the alignment ribs spaced equidistant from the bottom edge to the top edge of the front face. A plurality of siding panels is configured to attach to the foam backing panel, each siding panel having a top face and a bottom face, the top face configured to align with one of the alignment ribs such that the bottom face extends beyond an adjacent alignment rib.
Also disclosed herein are methods of making the backing and siding panel. One such method comprises providing a siding panel and joining a porous, closed cell foam to a substantial portion of a major surface of the fiber cement substrate, the foam providing a drainage path through cells throughout the foam.
Also disclosed in embodiments is a foam insulation board comprising: a front face and a rear face; a first side face and a second side face; and a top face and a bottom face. The top face includes a top joining element, and the bottom face includes a bottom joining element complementary in shape to the top joining element. The first side face includes a first joining element, and the second side face includes a second joining element complementary in shape to the first joining element. An adhesive is present on at least one face of the top joining element, the bottom joining element, the first joining element, or the second joining element.
Several specific embodiments are contemplated. In one embodiment, the top joining element is a tongue, and the one face with the adhesive is a front face of the tongue. In another embodiment, the top joining element is a tongue, and the one face with the adhesive is an upper face of the tongue. In a different embodiment, the bottom joining element is a groove, and the one face with the adhesive is a rear face of the groove. In another embodiment, the bottom joining element is a groove, and the one face with the adhesive is a lower face of the groove. In the next embodiment, the second joining element is a tongue, and the one face with the adhesive is a front face of the tongue. In another embodiment, the second joining element is a tongue, and the one face with the adhesive is a sideward face of the tongue. In still another embodiment, the first joining element is a groove, and the one face with the adhesive is a rear face of the groove. In a final embodiment, the first joining element is a groove, and the one face with the adhesive is a sideward face of the groove.
In some general embodiments, the one face with the adhesive is a front face of the joining element. In other general embodiments, the one face with the adhesive is a rear face of the joining element. In still some other embodiments, the one face with the adhesive is a sideward face of the joining element.
The adhesive may be covered with a pull-off strip. The adhesive may be a UV curable adhesive, a hot melt adhesive, a thermosetting or thermoplastic adhesive, a pressure sensitive adhesive, or a solvent-based adhesive.
The rear face of the foam board may further comprise drainage grooves. The foam insulation board may be made of expanded polystyrene. The foam insulation board may further comprise a plurality of registration ribs positioned longitudinally across the front face and spaced equidistantly.
Also disclosed herein are embodiments of foam backing panels that have alternating high density portions and low density portions. Fasteners used to attach the foam back panel to an exterior wall pass through the high density portions.
Also discussed herein are insulation systems that include a starter strip. The insulation system also includes (i) a foam backing board and a siding panel; or (ii) a composite panel made from a foam backer and a siding panel. The starter strip includes a channel adapted to receive the bottom face of the foam backing board or foam backer. The siding panel is sized to hide the starter strip when the foam backing board or foam backer is placed in the channel of the starter strip.
The description herein makes reference to the accompanying drawings wherein like reference numerals refer to like parts throughout the several views, and wherein:
a is a portion of the installation board shown in
a is a sectional view of an upper ship lap joint;
b is a sectional view of a lower ship lap joint;
a is a sectional view of the fiber cement board of the prior art panel;
b-8d are sectional views of fiber cement boards having various sized shadow lines;
a shows the cement board in
b shows the cement board in
c shows the cement board in
The invention outlined hereinafter addresses the concerns of the aforementioned shortcomings or limitations of current fiber cement siding 10.
A shape molded, extruded or wire cut foam board 12 has been developed to serve as a combination installation/alignment tool and an insulation board. This rectangular board 12, shown in
With reference to
Typical fiber cement lap siding panels 10 are available in 12 foot lengths and heights ranging from 5¼ inches to 12 inches. However, the foam boards 12 are designed specifically for a given profile height and face such as, Dutch lap, flat, beaded, etc. Each foam board 12 generally is designed to incorporate between four and twelve courses of a given fiber cement lap siding 10. Spacing between alignment ribs 14 may vary dependent upon a particular fiber cement siding panel 10 being used. Further size changes will naturally come with market requirements. Various materials may also be substituted for the fiber cement lap siding panels 10.
One commercially available material is an engineered wood product coated with special binders to add strength and moisture resistance; and further treated with a zinc borate-based treatment to resist fungal decay and termites. This product is available under the name of LP SmartSide® manufactured by LP Specialty Products, a unit of Louisiana-Pacific Corporation (LP) headquartered in Nashville, Tenn. Other substituted materials may include a combination of cellulose, wood and a plastic, such as polyethylene. Therefore, although this invention is discussed with and is primarily beneficial for use with fiber board, the invention is also applicable with the aforementioned substitutes and other alternative materials such as vinyl and rubber.
The foam boards 12 incorporate a contour cut alignment configuration on the front side 20, as shown in
To install the fiber cement siding, according to the present invention, the installer must first establish a chalk line 26 at the bottom of the wall 28 of the building to serve as a straight reference line to position the foam board 12 for the first course 15 of foam board 12, following siding manufacturer's instructions.
The foam boards 12 are designed to be installed or mated tightly next to each other on the wall 28, both horizontally and vertically. The first course foam boards 12 are to be laid along the chalk line 26 beginning at the bottom corner of an exterior wall 28 of the building (as shown
As the exterior wall 28 is covered with foam boards 12, it may be necessary to cut and fit the foam boards 12 as they mate next to doorways, windows, gable corners, electrical outlets, water faucets, etc. This cutting and fitting can be accomplished using a circular saw, a razor knife or a hot knife. The opening (not shown) should be set back no more than ⅛ inches for foundation settling.
Once the first course 15 has been installed, the second course 15′ of foam boards 12 can be installed at any time. The entire first course 15 on any given wall should be covered before the second course 15′ is installed. It is important to insure that each foam board 12 is fully interlocked and seated on the interlocking tabs 16 to achieve correct alignment.
The first piece of fiber cement lap siding 10 is installed on the first course 15 of the foam board 12 and moved to a position approximately ⅛ inches set back from the corner and pushed up against the foam board registration or alignment rib 14 (see
With reference to
Thereafter, a second course of fiber cement siding 10′ can be installed above the first course 10 by simply repeating the steps and without the need for leveling or measuring operation. When fully seated up against the foam board alignment rib 14, the fiber cement panel 10′ will project down over the first course 10 to overlap 34 by a desired 1¼ inches, as built into the system as shown in
The board 12, described above, will be fabricated from foam at a thickness of approximately 1¼ inch peak height. Depending on the siding profile, the board 12 should offer a system “R” value of 3.5 to 4.0. This addition is dramatic considering that the average home constructed in the 1960's has an “R” value of 8. An R-19 side wall is thought to be the optimum in thermal efficiency. The use of the foam board will provide a building that is cooler in the summer and warmer in the winter. The use of the foam board 12 of the present invention also increases thermal efficiency, decreases drafts and provides added comfort to a home.
In an alternate embodiment, a family of insulated fiber cement lap siding panels 100 has been developed, as shown in
The fiber cement composite siding panels 100 of the second preferred embodiment may be formed by providing appropriately configured foam backing pieces 132 which may be adhesively attached to the fiber cement siding panel 110.
The composite siding panels 100 according to the second preferred embodiment may be installed as follows with reference to
The new self-aligning, stack-on siding design of the present invention provides fast, reliable alignment, as compared to the time consuming, repeated face measuring and alignment required on each course with the present lap design.
The new foam backer 112 has significant flexural and compressive strength. The fiber cement siding manufacturer can reasonably take advantage of these attributes. The weight of the fiber cement siding 110 can be dramatically reduced by thinning, redesigning and shaping some of the profiles of the fiber cement 110.
The fiber cement siding panel may include a lip 144 which, when mated to another course of similarly configured composite fiber cement siding can give the fiber cement siding 110 the appearance of being much thicker thus achieving an appearance of an increased shadow line. Further, it is understood although not required, that the fiber cement siding panel 110 may be of substantially reduced thickness, as stated supra, compared to the 5/16″ thickness provided by the prior art. Reducing the thickness of the fiber cement siding panel 110 yields a substantially lighter product, thereby making it far easier to install. A pair of installed fiber cement composite panels having a thickness (D′) of 0.125 or less is illustrated in
The present invention provides for an alternate arrangement of foam 112 supporting the novel configuration of fiber cement paneling. In particular, the foam may include an undercut recess 132 which is configured to accommodate an adjacent piece of foam siding. As shown in
No special tools or equipment are required to install the new insulated fiber cement lap siding 100. However, a new starter adapter or strip 150 has been designed for use with this system, as shown in
The siding job can be started at either corner 29. The siding is placed on the starter adapter or strip 150 and seated fully and positioned, leaving a gap 154 of approximately ⅛ inches from the corner 29 of the building. Thereafter, the siding 100 is fastened per the siding manufacturer's installation recommendations using a nail gun or hammer to install the fasteners 36. Thereafter, a second course of siding 115′ can be installed above the first course 115 by simply repeating the steps, as shown in
The lamination methods and adhesive system will be the same as those outlined in U.S. Pat. Nos. 6,019,415 and 6,195,952B1.
The insulated fiber cement stack-on sliding panels 100 described above will have a composite thickness of approximately 1¼ inches. Depending on the siding profile, the composite siding 100 should offer a system “R” value of 3.5 to 4.0. This addition is dramatic when you consider that the average home constructed in the 1960's has an “R” value of 8. An “R-19” side wall is thought to be the optimum in energy efficiency. A building will be cooler in the summer and warmer in the winter with the use of the insulated fiber cement siding of the present invention.
In some particular aspects of the disclosure, the foam backing panel or foam insulation board includes an adhesive along one of the edges, which is useful for sealing the edges of adjacent backing panels or insulation boards to provide a uniform insulation layer with no cracks through which heat may be lost. The adhesive may be present on an entire edge or a portion thereof. For example, when the edges of the foam insulation board are arranged in a ship-lap configuration, one or all of the ship-lap surfaces may comprise the adhesive. In particular, the edge may have one or more faces on which the adhesive is present. More generally speaking, the horizontal and vertical edges of the insulation board are shaped to be complementary, which aids in joining them together and sealing any cracks between them.
In some particular aspects of the disclosure, the foam backing panel, whether made as a foam board or as a foam backer for a composite panel, is divided into an upper portion and a lower portion, the upper portion having a higher density than the lower portion of the foam backing panel. In this regard, a fastener, such as a nail or screw, is typically used to connect the foam backing panel to the exterior wall of the building being insulated. The fastener ultimately bears the weight of the entire siding. Damage can occur to the foam backing panel due to the heavy weight of some siding materials like fiber cement. Mechanical impacts to the siding or high wind conditions can also cause tearing or structural damage. The increased density of the upper portion, through which the fastener passes, reduces the damage that can occur to the foam insulating panel.
The foam board 310 has a front face 312, a rear face 314, a top face 316, a bottom face 318, a left side face 320, and a right side face 322. In this regard, the left side face 320 and the right side face 322 can also be considered as being a first side face 324 and a second side face 326. Here, the left side face 320 is labeled as being the first side face 324, and the right side face is labeled as the second side face 322. The top face 316 and the bottom face 318 may be considered to be horizontal faces of the foam board. The left side face 320 and the right side face 322 may be considered to be vertical faces of the foam board.
Referring to
Each alignment or registration rib 330 includes a bottom face 332, a top sloped face 334, and a front edge 336, wherein the bottom face and the sloped top face meet at the front edge. The bottom face 332 of the registration rib is perpendicular with the front face 312 of the foam insulation board.
In some embodiments, the rear face has at least one recess 390 that is positioned longitudinally across the rear face 314 of the foam board and runs from one side face 320 of the board to the other side face 322, generally parallel to the top face 316 and the bottom face 318. If more than one recess is present, the recesses are spaced equidistantly from each other. The recesses 390 are complementary in shape to the registration ribs 330 and are positioned at the same level as each rib, as seen in
The top face 316 includes a top joining element 340. The bottom face 318 includes a bottom joining element 350. The top joining element 340 is complementary in shape to the bottom joining element 350, such that panels stacked upon each other are joined together in a shiplap arrangement to mate tightly together. Here, the top joining element 340 is shown as a tongue along the rear face of the foam board. The tongue includes a front face 342 that faces in the forward direction, and includes an upper face 344 that faces in an upward direction. The bottom joining element 350 is shown as a groove along the rear face of the foam board. The groove includes a rear face 352 that faces in the rearward direction, and includes a lower face 354 that faces in a downward direction. Put another way, the front face 342 of the top joining element is directed in the opposite direction of the rear face 352 of the second joining element. Similarly, the upper face 344 of the top joining element is directed in the opposite direction of the lower face 354 of the bottom joining element.
In some embodiments, joining elements are also present on the side. Referring now to
It should be noted that the first joining element 360 and the second joining element 370 may be as simple as the first side face 324 and the second side face 326 being parallel planes. There is no requirement that the first and second joining elements must be a structure that extends from or protrudes into the respective side face.
The rear view of
The front view of
The adhesive which is used on the sides/edges of the foam board may be used over the entire surface or used in discrete locations. Suitable adhesives may include, but are not limited to, UV curable adhesives and hot melt adhesives, such as polyamines and urethanes, glue, thermosetting or thermoplastic adhesives, pressure sensitive adhesives or solvent-based adhesives. Desirably, the adhesive is a pressure sensitive adhesive, which forms a bond upon application of light pressure.
In particular embodiments, the foam board is packaged with the adhesive covered up with a pull-off strip.
Another especially desirable feature which may be present on any embodiment of the foam insulation boards discussed herein is a plurality or series of relative distance markers or indicators. Such relative distance markers 302 are visible on the embodiment seen in
The foam insulation board and the adhesive can be made and used with the common knowledge of one of ordinary skill in the art.
As will be appreciated, during the installation of the foam insulation backer boards or composite panels set forth herein, the first (e.g., bottom) course should be level because the alignment of subsequent courses (above the first course) can be affected by a misaligned first course. A starter strip can be installed at a bottom edge of a wall to simplify installation, making it easier for an installer to keep the first course of panels level and on the same plane.
In some other particular aspects of the disclosure, the foam insulation backing board can be divided into an upper portion and a lower portion, the upper portion having a higher density than the lower portion of the foam backing panel. In this regard, a fastener, such as a nail or screw, is typically used to connect the foam backing panel to the exterior wall of the building being insulated. The fastener ultimately bears the weight of the entire siding. Damage can occur to the foam backing panel due to the heavy weight of some siding materials like fiber cement. Mechanical impacts to the siding or high wind conditions can also cause tearing or structural damage. The increased density of the upper portion, through which the fastener passes, reduces the damage that can occur to the foam insulating panel.
The front face 512 here is shown to be flat, i.e. the distance between the front face 512 and the rear face 514 is generally constant between the top face 516 and the bottom face 518. The top face 516 includes a first joining element 540, and the bottom face 518 includes a second joining element 550. The first joining element 540 is complementary in shape to the second joining element 550, such that panels stacked upon each other are joined together in a shiplap arrangement to mate tightly together. Here, the first joining element 540 is shown as a tongue along the rear face of the foam board, and the second joining element 550 is shown as a groove along the rear face of the foam board.
A plurality of registration ribs 530 are positioned longitudinally across the front face of the foam board and run from one side of the board to the other side, generally parallel to the top face 516 and the bottom face 518. The ribs are spaced equidistantly from each other. Again, the foam board is generally designed to incorporate between four and twelve courses of siding.
Each course is defined by a pair of registration or alignment ribs. Put another way, a course is defined between adjacent registration ribs. For example, course 570 is defined by ribs 530 and 532. Please note that the top face 516 and bottom face 518 should also be considered as a registration rib because when adjacent panels are stacked upon each other, they have the same effect as the ribs 530. Each course is also separated into a high density portion or upper portion 552 and a low density portion or lower portion 554. The high density portion 552 and the low density portion 554 are separated here by the line having reference numeral 556. The high density portion 552 is located above the low density portion 554 in each course. The high density portion 552 and the low density portion 554 both run from the front face 512 to the rear face 514. Again, the high density portion 552 has a height 553 and the low density portion 554 has a height 555, measured on the rear face 514 of the foam board. The height 557 of each course is the sum of the two heights 553 and 555. Generally speaking, there is no “middle” portion between the high density portion and the low density portion, although there may be a thin layer between the two portions where the density changes rapidly. Generally, the high density portion of each course has the same density, and the low density portion of each course has the same density. Put another way, the foam board 510 can be described as having alternating high density portions 552 and low density portions 554 between the top face 516 and the bottom face 518.
A siding panel 560 is aligned with each course and attached using a fastener 562 which passes through the high density portion 552 of each course. Again, this increases the stability of the foam board 510. The top edge of each siding panel is abutted and positioned by a registration rib 530.
In addition, the foam board 510 itself might be attached to the exterior wall 501 separately from the siding panels 560. In such embodiments, the portion of the foam board through which the fastener 568 passes should also be of high density. Thus, as depicted here, the first joining element 540 which rises above the top face 516 is also of high density. Put another way, the density of the first joining element is greater than the density of the low density portion of each course. In yet more specific embodiments, the density of the first joining element is equal to or greater than the density of the high density portion of each course.
It is contemplated that the foam insulation board contains a visual indicator that permits the installer to distinguish between the high density portion 552 and the low density portion 554. For example, as illustrated in
The ratio of the height of the high density portion to the height of the low density portion may be from about 2:1 to about 1:3, or more specifically from about 1:1 to about 3:2.
The high density portion may have a density of from about 200 to about 640 g/cm3, or more specifically from about 250 to about 500 g/cm3. The low density portion may have a density of from about 16 to about 350 g/cm3, or more specifically from about 20 to about 200 g/cm3. The high density portion is of course always denser than the low density portion. However, it should be noted that the difference in density between the high density portion and the low density portion is generally at least 50 g/cm3.
The foam insulation board of
While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the fiber cement siding board disclosed in the invention can be substituted with the aforementioned disclosed materials and is not to be limited to the disclosed embodiments but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims, which scope is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures as is permitted under the law.
This application is a continuation-in-part of U.S. patent application Ser. No. 12/817,313, filed on Jun. 17, 2010, which is a divisional of U.S. patent application Ser. No. 11/025,623, filed on Dec. 29, 2004, now U.S. Pat. No. 7,762,040, which claimed priority to U. S. Provisional Patent Application Ser. No. 60/600,845 filed on Aug. 12, 2004. This application is also a continuation-in-part of U.S. patent application Ser. No. 13/241,949, filed on Sep. 23, 2011, which is a continuation-in-part of U.S. patent application Ser. No. 12/817,313, filed on Jun. 17, 2010, which is a divisional of U.S. patent application Ser. No. 11/025,623, filed on Dec. 29, 2004, now U.S. Pat. No. 7,762,040, which claimed priority to U. S. Provisional Patent Application Ser. No. 60/600,845 filed on Aug. 12, 2004. This application is also a continuation-in-part of U.S. patent application Ser. No. 13/241,684, filed on Sep. 23, 2011, which is a continuation-in-part of U.S. patent application Ser. No. 12/817,313, filed on Jun. 17, 2010, which is a divisional of U.S. patent application Ser. No. 11/025,623, filed on Dec. 29, 2004, now U.S. Pat. No. 7,762,040, which claimed priority to U. S. Provisional Patent Application Ser. No. 60/600,845 filed on Aug. 12, 2004. The disclosures of these applications are hereby fully incorporated by reference in their entirety.
Number | Date | Country | |
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60600845 | Aug 2004 | US |
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Parent | 11025623 | Dec 2004 | US |
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Parent | 12817313 | Jun 2010 | US |
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Parent | 13241949 | Sep 2011 | US |
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Parent | 12817313 | Jun 2010 | US |
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Parent | 13241684 | Sep 2011 | US |
Child | 12817313 | US | |
Parent | 12817313 | Jun 2010 | US |
Child | 13241684 | US |