The invention pertains generally to a mechanical device and method for attaching solar panels (that is, photovoltaic panels), or a series of panels, to the surface of a roof. In particular, this invention pertains to apparatus and methods for attaching thin film and framed solar panels in a way that can be readily installed on and removed from a variety of different type roof surfaces, is durable, lightweight, accommodates the various weather conditions encountered by such systems, including the differing coefficients of thermal expansion between whatever the roof material upon which the panels are installed and the panels themselves, is attractive, and is cost effective.
With the increasing cost and demand for energy in all forms and in all applications, alternative sources for energy continue to be sought and utilized. One example of this is the commercial and residential use of solar energy. Particularly in the commercial arena, designers, developers and owners of large commercial buildings are increasingly considering alternative sources of core and/or supplemental energy rather than face the certainty of price increases and the uncertainties of availability in the future. Indeed, some commercial users intend to provide electricity generation not only for their own on-site consumption, but also for sale of power to the local community utility companies.
One of the most popular means for on-site power generation is solar power. The use of solar power is of course not new. The harnessing and use of solar power by mankind probably dates back to the 7th Century B.C., when magnifying glasses were used to focus light on a fuel to light a fire for light, warmth and cooking. It is reported that in the 2nd Century B.C., the a fuel to light a fire for light, warmth and cooking. It is reported that in the 2nd Century B.C., the Greek scientist Archimedes used focused and reflected sunlight to set attacking Roman ships afire.
A popular solar-powered, electrical generation device is the photovoltaic system that converts light into electricity. The basic light-to-electricity phenomenon (sometimes referred to as the photovoltaic or PV effect) was first discovered in 1839. But it took nearly another century before scientists truly understood this process, and it was discovered that the conversion process occurs at the atomic level. During that time, many renowned scientists became interested in the PV effect. Even Albert Einstein published a paper on it in 1905.
The actual birth date for modern photovoltaic technology is traced back to 1954, when scientists Chaplin, Fuller and Pearson, all at Bell Labs, developed the silicon photovoltaic cell—which was the first solar cell that was capable of generating enough power to run common electrical equipment. Interestingly, solar-powered dollar bill changers were among the first products to be solar powered. Perhaps the most significant early utilizations of PV cells were on satellites. In 1958, a small PV array was used on the Vanguard I space satellite to power its radios. Later that same year, satellites Explorer III, Vanguard II and Sputnik-3 all included PV-powered systems onboard. The efficacy and reliability of PV was now established, and by the next decade, selenium and silicon cells were being commercially produced and sold.
In 1972, the University of Delaware established the Institute for Energy Conversion to do research on and development of thin-film photovoltaic and solar thermal systems, and that Institute built a PV/thermal hybrid system that used roof-integrated arrays to feed power through a special meter to the local utility company during the day, and then lower-cost power was purchased during the sun-less night. The roof-integrated PV system had been borne.
Not long thereafter, the energy crisis, with its long lines at the gas pump and spiking gas prices, fanned the public interest in non-fossil fuels, and solar power was at the top of the list. So much so that the U.S. Government launched the Solar Energy Research Institute as part of the Department of Energy. And interest in photovoltaic systems, which were already being used in many commercial applications, became similarly attenuated. That interest has essentially continued unabated since.
Therefore, for over thirty years, it has been know that photovoltaic products, including thin film products, could be attached to the roof of buildings in order to generate electricity. And in that time, an entire industry has evolved that is devoted to that very thing, and that industry has, over that time, developed a number of methods for attaching the panels to a roof. Many of the systems have involved mechanically attaching the panels directly to the roof system surface using, for example, bolts or screws or other similar devices. Of course, these systems inherently involved drilling holes into the roof system surface or otherwise disturbing the integrity of the roof surface, particularly over time as inclement weather, wind and heat (with the differing coefficients of expansion between the panels and the roof surface) created stresses at the attachment points. This could and often did lead to compromising the water repellant properties of the roof or worse. Accordingly, attachment systems that did not puncture the existing surface were preferred. Also, for significant tax reasons, having the system not be permanently attached to the roof of the structure was often preferred. Therefore, attachment systems in which the panels were removably secured on the roof top were developed.
A commonly used system involved the panel/frame systems being simply laid on the roof material and weighed there using ballast blocks. Needless to say, building the frame and using ballast blocks to hold them down onto the roof added costs, components and weight to the system. Some existing systems may not have been initially engineered to withstand the added weight of the panels and ballast. Accordingly, the cost not only to purchase and install the panels and the ballast, but to also reinforce to roof system may have proven prohibitive. The ballast weight may need to be substantial because the solar panels, by definition, must cover a relatively large area in order to be effective. Therefore, they may be subjected to very high winds, and the ballast needs to keep the panels and support structure in place, otherwise they can become an airborne projectile that can cause damage to people and property.
The added costs, inconvenience and weight affiliated with these ballast-type systems created the need in the industry for a better apparatus and method to attach solar panels, and particularly thin film panels, to an existing roof system.
While this development was ongoing in the field of photovoltaic panels and their use in roof-based systems, a Swiss engineer, Georges de Mestral, who had become intrigued with the way in which seeds from a particular plant that grew in the Alps so securely stuck to his clothing and to the fur of his dog after their daily summer walk, was developing the hook and loop attachment technology. In 1941, upon examining the seeds and how they became attached to his dog and himself more closely, Mr. de Mestal saw that the spherical seeds had tiny hooks on the end of their needle-like projections, and those hooks mechanically attached themselves to the fabric in his clothing and his dog's fur, from which they could be removed, but with considerable effort. He saw the possibility of using a similar arrangement to bind two materials together securely but reversibly in a simple fashion. Thus was born the now well-known hook-and-loop attachment system, which de Mestral named VELCRO®, now a registered trademark of the Velcro USA company, headquartered in Manchester, N.H. The hook-and-loop attachment system has been used for many varied applications, from all sorts of clothing as replacement for buttons and zippers, for children's shoes to replace the laces, and to many strap-like applications to replace buckles, as the hook material on one side of the strap will adhere to the loop material on the other side of the strap when it is wound upon itself.
Prior to the work on the inventions herein described, however, it is believed that no one has even attempted to apply hook-and-loop technology as an attachment mechanism for adhering solar panels to roof systems, let alone done so successfully. Indeed, the applicant is in the process of working with Velcro USA on a supply agreement for the embodiments shown herein, and the representatives at Velcro USA with whom applicant have dealt have also confirmed that they too are unaware of anyone before applicant utilizing the Velcro® hook and loop material for the applications herein described.
That hook and loop material has not previously been used in this application is not surprising. For one thing, it is extremely important that once solar panels are put into place on a roof, that they stay there. Unfortunately, by definition solar panels must be exposed to the elements, including the wind. And in certain situations and environments, the solar panels can be exposed to wind gusts up to and even in excess of 100 mph. Earthquakes can also cause the solar panels to move if not adequately secured. Because of the risk of injury to property and to persons if the solar panels move, or worse, become airborne in the wind, require that whatever method and mechanism are used to secure the panels to the roof, they must be adequate to hold the panel in place even in extreme conditions. Given these concerns, it is not surprising that using hook-and-loop technology has not previously been used, and would not be an obvious choice to use, as the means and method to attach these panels to a roof.
Utilizing the methods and apparatuses hereinafter described, a system for attaching solar panels is achieved which is lightweight (typically less than 1 pound per square foot of coverage) such that re-engineering of the existing roof system is not required; is low cost (requiring less time, personnel, hardware and equipment to install); provides for rapid electrical integration; requires no roof penetration; requires no ballast; presents no added roof obstacles beyond the panels themselves; is easily removable, if necessary, without damage to the roof system; can be applied not only to flat roof systems, but also to sloped and curved roof systems; can be easily configured to accommodate existing roof installations; and is aesthetically pleasing, among other advantages.
The present invention uses a hook-and-loop system as the attachment means to adhere the solar panels to the roof top material, or to an intermediary structure. This can be used with either the flexible thin film solar panels, or with framed solar panels. This can be used to attach the framed panels directly to the roof surface, or to racks or other intermediate structures that are in turn attached to the roof. The hook material can be attached using any suitable means such as adhesive along the edges of the underside of the flexible thin film solar panel, and the loop material can be attached directly to the top of the roofing systems, again using any suitable means, such as adhesive, in an area that coincides with the preferred arrangement of the panels on the roof, so that the hook and loop aspects properly align and mate upon installation. In the preferred embodiment, it has been found that for ease and success of installation, the entire underside of the thin film solar panels can be fitted with either the hook or the loop material, and that the other portion can be strategically placed on the roof, thereby eliminating the need for the two portions to be exactly aligned before attachment. In another preferred embodiment, the hook material, being less expensive than the loop material, is attached to the underside of the panel, and the loop material is attached to the roof. In another preferred embodiment, the hook material is thermally bonded directly to the underside of the panel during the construction of the panel, preferably a Uni-Solar PVL-136 Panel, so as to eliminate the need for an adhesive layer between the hook material and the underside of the panel. In yet another preferred embodiment, the solar panels are first housed or adhered to steel, metal or plastic frame-like or rack-like substrate (which can have flat or corrugated underside, and then the substrates can be attached to the roof system using hook and loop. In yet another preferred embodiment, the substrate is formed into customized channels or track into which the thin film panels are inserted, and then the track is attached using hook and loop material. In the preferred method, the amount of area required for hook and loop attachment is calculated to ensure that the panels, once attached, remain in place.
In another preferred embodiment on the present invention, either the loop or hook material can be directly adhered, or imbedded into, the upper layer of a built-up roofing membrane material during its construction.
Utilizing this system, the panels can be attached in a way that is very cost effective, and does not add weight to the roofing system. Also, the hook and loop material will absorb some movement between the solar panels and the roof system which occurs dues to the differing coefficients of heat expansion between the two different materials. Therefore, the roofing system nor the panels will be subjected to damaging stress as the panel and the roof system are repeatedly cycled through the heat of the day and the cold of the night.
A shown in
As shown in
The preferred adhesive layers 12 and 18 for this embodiment is available from Sika Corporation, SikaLastomer®-68 ethylene propylene copolymer tape, as it has been found to have acceptable strength and durability, and compatibility with the material on the underside of the most commercially available flexible solar panels 10. It has also been found to be suitable for attachment to most roof system surfaces 20. Because, however, there are many different types of roof surface materials, any adhesive 18 must first be tested to confirm that it will properly adhere to and is compatible with the roof surface 20, but also care should be taken to ensure that application will not adversely affect any warranty that may then be extant for the roof system and/or surface.
The adhesive layer 18 is applied to the underside of the loop portion 16, and then that combination is applied directly to the roof surface 20. It is important, of course, to ensure that the roof surface 20 is free of contaminants or other material that would impede a good bond between the adhesive layer 18 and the surface 20. Utilizing thin film panels 10 provides a flexible, lightweight system that will find utility with most roof systems, and will be particularly useful and applicable in situations that involve curved or sloped roof systems, or where the existing roof system is not engineered to accommodate significant added weight, or where aesthetics of the roof after installation is a design criteria.
In addition to thin film flexible solar panels, also commercially available are framed solar panels 22 in which the panels are not flexible, but are typically constructed of some type of rigid material housed within a protective metal frame 24. In that circumstance, the hook material 14 can be attached using the adhesive 18 to the metal frame 24, and the mating loop material 16 attached to the roof as described above.
Turning to
Using this pre-bonded panel-and-hook-material component eliminates the need for the separate step of applying the hook material to the underside of the panel in the field, and also eliminates a separate component that must be applied in the field, such as additional adhesive material tape that can be used to attach the hook material to the underside of the panel. Also, application of the hook material 14 to the solar panel during or immediately after the manufacturing process will ensure a superior and more reliable attachment that will not be affected by conditions at the job site, or dependent upon the skill of the installer.
In this embodiment, the entire underside of the panel is affixed with hook material 14. Although for most installations, less than all of the directly-bonded hook material 14 will be mated with loop material, it is still believed that the benefits to be derived from direct-bonding outweighs any material cost saving that could realized by only applying the amount of hook material 14 actually needed at the job site.
Any of the conventional means for direct bonding of the hook material 14 to the underside of panel 10 could be used. For example and not limitation, a thermal bonding or other heat weld could be employed; or any suitable adhesive material could be used, such as a polymer adhesive of the types available from various vendors, such as Du Pont.
Turning to
At this point, it should be noted that there are many different types of roof system surfaces 20 that may be encountered in the field. Some of the more typical surfaces to which solar panels may be attached using the means and methods discussed herein are white membrane, metal, PVC or foam. Of course, in order for the means and methods discussed here to be utilized, the roof system surface 20 must be of a type to which an adhesive will adequately adhere in terms of strength of bond, durability of bond, and lack of damage to the surface material. If the roof system surface 20 is not of such a material, then an intermediately step to coat the surface with a material that will provide such a suitable attachment material may be necessary. For example, for a foam-type roof system surface, it has been found that first applying a coating of HYDRO Bond #7 primer to the foam will create an upper surface to which the loop material 16 can be readily attached. It has also been discovered that if desired the loop material 16 can be directly embedded in the still-wet primer after it is applied, and that once attached, the loop material is adequately secured. For another example, some roof system surfaces 20 or topped with an asphalt material. It has also been discovered that the loop material 16 can be directly embedded in the asphalt material, and that too will provide a suitable attachment. Such an arrangement is graphically depicted in
Of course, it is also possible to apply all of the various components of the sandwich—panel 10, tape 12, hook material 14 and the desired amount of the loop material 18—initially and before taking these sandwiched components to the job site. Such an arrangement is shown in
It would also be possible to assemble and join by any suitable means a number of adjacent panels 10 to create a wide array 28, as is depicted in
As mentioned above, in addition to thin film flexible solar panels, other commercially available solar panels are rigid and sold pre-framed. The attachment means and methods herein described can also be adapted for attachment of them to roof system surfaces 20 as well. Two such attachment methods are shown in
A slightly different embodiment is shown in
An alternative means for attaching either framed or unframed rigid solar panels is shown in
As mentioned above, the units 42 can be in the form of elongate rails or shorter blocks. In most instances, the shorter block configuration will be preferred so as to reduce cost. As with all other installations, however, it will be necessary to ensure that the coverage area of mated hook and loop material is sufficient to withstand the design wind pressure and uplift force on the installed panels.
It is of course important that each and every installation being approached as a unique project that must be considered independently in terms of, among other things, the amount of mated hook and loop material 14 and 18 that must be applied. In this regard, the steps discussed below (and generally summarized in
A sample spreadsheet showing a table of the calculation performed for a different type structures in an area rated for wind pressure of 75 miles per hour, and a grade “C” exposure, is set forth here (references to Figures, Tables and Sections are to those referenced items in the California Building Code, and references to “Velcro” are references to Velcro® hook and loop product, and specifically to Velco® hook model 752 and loop model 3001:
It has also be discovered that either the hook or the loop material can be added to certain membrane type roofing materials during the construction process by which the membrane type roofing material is produced. These membrane materials are typically used to finish a roofing system, being the final or top layer of the typical roof system installation before the placement of solar panels. These typical membranes are manufactured in strips that are then transported to the roof construction site, and are applied to the roof structure to create the water- and weather-proof top layer of the roofing system. For example, one type of roof structure may have metal or other material as to the upper construction material. In finishing the roof system, a layer of insulation might be added to the top of the upper construction material and fixedly attached by means of screws that screw into the upper construction material. On top of the insulation, additional layers of primer or other adhesive material may be applied as a coating, and then the strips of membrane material applied to that coating. The strips of membrane material are typically laid down side-by-side and end-to-end, with a small area of overlap at each junction. The overlap areas are typically adhered together by either adhesives or by a heat welding process in which the overlap areas are locally heated to return the membrane material in that region to a sufficiently molten state that the overlapped areas will meld and bond upon cooling, creating a seamless, strong upper roof surface.
There are many different types of membrane roofing materials, but one common type utilizes a build-up process of construction in which a first layer of material, such as a fiberglass mesh, is laid down and then which are added layers of a liquid or liquids that sufficiently harden upon cooling to provide the desired finished product. In the construction process for such membranes, it is possible to add either the hook or loop material to the membrane during the final stages of manufacture such that the membrane that is then delivered to the job site is already fitted with the hook or loop material, thus avoiding the step in the field of attaching the hook or loop material to the membrane after it is installed on the roof (as was described above).
As discussed above, it is preferred to attach the less expansive hook material to the underside of the solar panels, so that the entire underside can have hook material at a lower cost than would be possible if the entire underside were covered with loop material. Therefore, it is preferred that only strips of the loop material be attached to the membrane.
Looking at
Looking at
Also, because it is intended that the membranes 68 with embedded strips 70, 72 and 74 will usable for most jobs, it will be required that the amount of loop surface area provided by the strips 70, 72 and 74 be sufficient for the vast majority of jobs (as determined by the method described above) so that the cross-sectional area of hook and loop attachment after the solar panels are installed to meet or exceed design specifications. Therefore, it is preferred that each membrane 68 will have the three strips 70, 72 and 74, and that each strip will be approximately 2 inches wide, evenly spaced and approximate 11 to 12 inches between the middle strip 72 and the two outer strips 70 and 74, on the typical membrane that is approximately one meter in width. If the width of the manufactured membrane 68 is material more or less wide than one meter, the width of the strips will have to be adjusted accordingly.
As shown in
Although various specific embodiments have been set forth above, it will be clear to those skilled in the art that the inventive concepts herein disclosed are not limited to those specific embodiments. Accordingly, the scope of the protection herein provided is not limited to the specific embodiments, but is of the full scope of the following claims, including equivalents thereto.
This application is a continuation in part of the application of same title filed Apr. 5, 2007, Ser. No. 11/784,244, and is incorporated herein fully by reference.
Number | Date | Country | |
---|---|---|---|
Parent | 11784244 | Apr 2007 | US |
Child | 11894287 | US |