Patent Application
20100294340
1. Field of the Invention
This invention relates to solar module frames for mounting solar panels to a structure.
2. Discussion of Related Art
Solar technology seeks to convert energy from the sun into electricity and reduce demands on conventional sources of electricity, such as fossil fuels. The need for renewable energy sources exists in areas with temperate climates as well as areas with winter climates. Solar cells convert sunlight into direct current. Typically, multiple solar cells are positioned between substrate plates or sheets, one of which is transparent to light, and the plates with the solar cells there between formed into solar panels. Such solar panels are usually of a convenient size for handling and for mounting on a roof or other structure, and such panels are typically rectangular in shape.
Solar panels are typically somewhat flexible and are typically set in a supporting frame. Conventional frames that use open channel designs allow bending and/or twisting of parts of the frame when under load, such as from wind or snow accumulation. The wind and the snow loads can damage the solar panel.
Solar modules mounted on the shorter sides of the rectangular shaped solar panel result in a span the length of the solar panel. This arrangement when under load has downward deflection at the center of the span as well as twisting and/or spreading of the frame. The load on the panel may cause the frame to fail when a portion of the solar panel comes out of or disengages the frame due to the twisting or spreading of the frame. This failure also often damages the solar panel requiring replacement of the solar panel.
Structures, such as rooftops, are not always uniform have irregularities which require added installation steps, for example, drilling additional holes in the frame to mount the solar module.
One object of this invention is to provide a solar module with a frame for mounting to a structure. There is a need for a frame that can withstand wind and snow loading, for example, according to the IEC 61215, Second edition standard without failing and while not increasing the mass of the solar module over conventional frames. There is also a need for a frame that provides flexibility during installation to allow for irregularities in the structure, such as without drilling additional holes in the frame.
These and other objects of this invention are accomplished with a frame for mounting a solar panel that includes at least one tubular member with a generally triangular cross section taken transverse to a length. The tubular member includes a riser element connecting generally perpendicular to a span element and a truss element extending from the riser element and the span element. The frame includes a flange in combination with the tubular member for receiving at least a portion or a part of the solar panel.
According to certain embodiments of this invention, a solar module with a frame exceeds the strength of the conventional design by at least about twice and more specifically by more than about 2.6 times. The overall strength includes resistance to bending or bowing, particularly at the center and twisting under load which can reduce frame member spreading and failure of the solar module. The improved strength of the frame can exceed requirements of the IEC 61215, Second edition standard for wind and snow loadings.
According to certain embodiments of this invention, the truss element has a curved or arcuate profile or shape. This curved profile may include convex, concave and/or combinations of convex and concave sections or segments with respect to the riser element and the span element. Generally, a convex section can have a knee or a point of inflection, such as closer to the span element than the riser element.
The frame may include other members, such as rectangular shapes. The frame may mount around or along a perimeter of the solar panel. Solar panels may include solar cells, a transparent sheet and a backing sheet. Solar panels, typically, but not necessarily, are rectangular.
The frame members may have any suitable dimension, such as a wall thickness of about 0.5 mm to about 2.5 mm, a height of about 30 mm to about 80 mm and a width of about 10 mm to about 45 mm.
Optionally, the frame may include a sealant along at least a portion of the frame, the flange and/or the solar panel. The sealant keeps out water and may increase the structural rigidity of the solar module.
The span element may form a connection channel along at least a portion of the length of the frame member for receiving or sliding at least a portion of an anchor into the member and attaching it to the structure. The connection channel can provide installation without the need to drill additional holes in and/or through the frame, for example, to compensate for misalignment from an uneven roof. The connection channel may prevent axial rotation of the anchor, such as by holding a head of anchor against a wall or other suitable structure to engage the anchor.
The members of the frame may include at least one attachment boss on or within the frame members for receiving at least one fastener, such as a tapered screw. Attachment bosses help to join or mate frame members, such as at butt joints or lap joints forming corners of the solar panel. Butt joints can be efficiently made during fabrication and installation.
The frame may further include mounting rails receiving the anchor from the connection channel and mounting to the structure. The mounting rails can be arranged in an end mount orientation or an intermediate mount orientation with respect to the solar panel.
This invention also includes an array of solar modules disposed on a structure, for example, arranged in rows and/or columns. Other aspects of this invention include a method of anchoring the solar module that includes providing a solar module with a frame having a connection channel, sliding a portion of at least one anchor into the connection channel and connecting the at least one anchor to the structure.
According to other embodiments of this invention, the frame includes an extruded member for mounting a solar panel to a structure. The extruded member includes a series of linear portions and arc portions arranged to form a generally triangular shape. The extruded member may also include curved fingers forming c-shaped bodies, such as for receiving a part of a fastener. Optionally, the frame may also include a groove along the outside perimeter, such as about 0.5 mm to about 1.5 mm deep and about 5 mm to about 15 mm wide.
The above and other features and objects of this invention are better understood from the following detailed description taken in view of the drawings wherein:
The invention, as shown in
Electricity broadly includes direct current, alternating current, low voltage, high voltage and/or any other suitable moving of electrons for transmission, storage and/or work. Often, solar modules 14 produce direct current which may be transformed to alternating current, for example, by an inverter.
As shown in
Solar panel 12 can be any suitable size and/or shape. Typical dimensions of solar panel 12 may range from fractions of one meter to several meters, such as, for example, a rectangle having a width of about 0.5 m to about 3 m and length of about 1 m to about 5 m. Generally, solar panel 12 can be carried or maneuvered by one person without additional powered lifting equipment. The size of solar panel 12 can be a function of various factors including, but not limited, to material strength, material cost, weather, location, and any other variable impacting design. According to certain embodiments of this invention, solar panel 12 can be about 0.75 m to about 1.1 m by about 1.5 m to about 1.7 m. According to other embodiments of this invention, solar panel 12 can be about 1.7 m by about 1.0 m.
Solar cells 56 may include, without limitation, single-crystal silicon, polycrystal silicon or multicrystal silicon, ribbon silicon, amorphous silicon, cadmium telluride, thin film and/or any other suitable photovoltaic form or element to covert electromagnetic radiation. Typically, any suitable number of solar cells 56 can be arranged within solar panel 12 in series and/or parallel configurations. According to certain embodiments of this invention, solar panel 12 includes sixty solar cells 56. According to other embodiments of this invention, solar panel 12 includes seventy-two solar cells 56.
Transparent sheet 58 includes at least a portion that can pass at least a substantial amount of the desired wavelengths of electromagnetic radiation for capture or conversion by solar cells 56. Materials for transparent sheet 58 may include glass, plastics and/or any other suitable transmissive substance. Generally, transparent sheet 58 can withstand some deflection or bending before cracking or failing. According to certain embodiments of this invention, transparent sheet 58 includes float glass.
Backing sheet 60 may include metals, plastics, laminates, wood members and/or any other suitable materials to at least partially isolate solar panel 12. According to certain embodiments of this invention, backing sheet 60 can be any suitable metallic foil, such as aluminum (Al), and/or polymeric material, for example, polyethylene terephthalate (PET), high density polyethylene (HDPE), polypropylene (PP), Tedlar®, Teflon®, Tefzel® and/or any other suitable fluorinated film. Backing sheet 60 may include laminated or layered structures, such as, for example, Tedlar®/PET/Tedlar® and/or Tedlar®/Al/Tedlar®.
Suitable adhesive materials or glues may be used to join or laminate transparent sheet 58 and/or backing sheet 60 with solar cells 56. Generally, adhesive materials can withstand the working temperature ranges of solar panel 12 and can be at least moisture resistant.
As shown in
Frame 10 according to certain embodiments of this invention meets or exceeds, by as much as 20%, the IEC 61215, Second edition standard while having no significant mass increase or change in overall dimensions of solar module 14 compared to conventional frames, not shown.
Compliance with the IEC 61215, Second edition standard allows for solar module 14 to withstand loadings, such as from wind and/or snow accumulation without failure of components since only minimal twisting or bending of frame members occurs. According to certain embodiments of this invention, frame 10 withstands at least 2400 Pa pressure when end mounted, such as from wind loading. According to other embodiments of this invention, frame 10 withstands at least 5400 Pa pressure, such as from snow loading.
Typical failure mechanisms of solar module frames under load or burden include downward deflection or bowing and include twisting or bending of frame members, particularly of the lengthwise members. Twisting of the members may result in a spreading or increasing the frame width until at least a portion solar panel 12 dislodges or pops out of at least a portion of flange 22 of frame 10.
Suitable materials for frame 10 may include aluminum, aluminum alloys, steels, stainless steels, alloys, polymers, reinforced polymer composites and/or any other suitable relatively lightweight and durable substance. Materials can be further treated, such as, for example, painted, galvanized, powder coated, anodized and/or any other suitable technique for improving form and/or function of frame 10. According to certain embodiments of this invention, frame 10 includes 6005-T5, 6061-T6 and/or 6063-T6 aluminum alloys.
Lap joints, butt joints 38, dovetail joints, mortise and tenant joints, miter joints and/or any other suitable union may form frame 10 from the same or different shaped members. According to certain embodiments of this invention and shown in
Frame 10 forms corners or angles that may include fasteners 36, such as, for example, screws, bolts, nuts, dowels, washers, rivets, biscuits, cements, glues, epoxies, welds and/or any other suitable mechanical or chemical attaching mechanisms. According to a certain embodiments of this invention, fasteners 36 include at least two machine screws at each corner of frame 10. Fasteners 36 may be counter sunk to minimize protrusions from frame 10, such as to create a smooth perimeter.
Solar panel 12 may be placed in frame 10 with further assistance of calking, glue, adhesive sealant 62 and/or other gasketing material in, on, around and/or between at least a portion of frame 10 and at least a portion of solar panel 12, as shown in
Typically, frame 10 includes one or more members having a cross section taken transverse to a length. Common manufacturing methods for frame members may include casting, extruding, milling, machining, stamping, pressing, molding and/or any other suitable mass production process. According to certain embodiments of this invention, frame 10 comprises extruded aluminum members.
Frame members can be any size or shape needed to perform the desired functions of frame 10. Typically, but not necessarily, a frame member has a length generally equal to a side of solar panel 12. According to certain embodiments of this invention, frame members have a height of about 30 mm to about 80 mm and a width of about 10 mm to about 45 mm. According to other embodiments of this invention, frame members have a height of about 50 mm and a width of about 26.5 mm.
Frame members may have wall portions with any suitable thickness or dimension. According to certain embodiments of this invention, frame members have a thickness of about 0.5 mm to about 2.5 mm. According to other embodiments of this invention, frame members have a thickness of about 1.3 mm to about 1.9 mm and more specifically about 1.57 mm.
Generally, outside corners of frame members can be rounded, smoothed, radiused, chamfered and/or remain sharp. Similarly, inside corners of members can be rounded, smoothed, radiused, chamfered and/or remain sharp. According to certain embodiments of this invention and as shown in the
According to certain embodiments of this invention, frame members include a cross section with an ergonomic design or shape to further assist gripping and handling of frame members, such as, for example depressions, ridges and/or bulges.
Members of frame 10 may include tubular members 18 and rectangular members 20, as shown in
As shown in
As shown in
As further shown in
Riser element 24 and span element 26 may connect or meet in any suitable location and at any suitable angle. According to certain embodiments of this invention, riser element 24 and span element 26 may form about a right angle, such as in a perpendicular, a generally perpendicular or a substantially perpendicular connection forming a vertex of a right or a near right triangle.
As further shown in
Truss element 28 may connect or meet with at least one of riser element 24 and span element 26 at any suitable location and at any suitable angle. According to certain embodiments of this invention, truss element 28 connects with riser element 24 and span element 26 to form a hypotenuse or a hypotenuse-like side of a triangle. Truss element 28 generally imparts structural rigidity to tubular member 18, particularly along a length of tubular member 18.
According to certain embodiments of this invention and as shown in
Typically, but not necessarily, convex shape 30 includes at least one knee 32 or point of inflection where the shape of the profile changes with respect to one or more discrete or distinct points. Knee 32 can form a bulge or a generally hump-like shape of any suitable size and/or shape. Knee 32 may be located at any position along or with respect to truss element 28. According to certain embodiments of this invention, knee 32 is located or positioned closer or nearer to span element 26 than riser element 24 along truss element 28, such as about the first one fifth to about one half of the distance along truss element 28, starting from where truss element 28 meets span element 26, or such as about one fifth to about two fifths of such distance, or such as about one third of such distance. According to certain embodiments of this invention, knee 32 has a curve of about 10 degrees to about 85 degrees and more specifically about 30 degrees. Typically, knee 32 can have a radius of about 10 mm to about 70 mm, more specifically about 30 mm taken from a point within the tubular member 18.
Tubular member 18 may include one or more extending lips, projections and/or ridges from the cross section of any suitable size and/or shape, for example, to aid in attaching or mounting tubular member 18 to structure 16.
Tubular member 18 may include at least one flange 22 in combination with tubular member 18 for receiving at least a portion of solar panel 12. Flange 22 can form a groove, a lip, a channel, a recess, an edge, a clip and/or any other suitable holding or anchoring structure for solar panel 12. According to certain embodiments of this invention, flange 22 includes a two-sided or a three-sided channel open toward an inside of the frame 10 for mounting at or along a perimeter of solar panel 12.
A depth of flange 22 or top to bottom distance may typically accommodate and/or allow a thickness of solar panel 12 to form, for example, a friction or an interference fit. Alternately, flange 22 may allow for the additional gasketing and/or adhesive sealant 62 as discussed above. Flange 22 can have any suitable width or side to side dimension. According to certain embodiments of this invention, the width of flange 22 is about 5 mm to about 22 mm. According to other embodiments of this invention, the width of flange 22 is about 11 mm, in the horizontal direction of flange 22, such as shown in
As shown in
Attachment boss 34 may be tapped and/or threaded during fabrication or installation, but generally can be cut by fastener 36, for example, with a tapered screw during assembly. Attachment boss 34 is not limited to straight or square shapes but also may include curved forms. Attachment boss 34 may be located at any location with respect to tubular member 18, particularly along an outside and/or an inside of the cross sectional shape. According to certain embodiments of this invention, at least two attachment bosses 34 are generally located at vertices of the generally triangular shape. Attachment bosses 34 may further improve structural rigidity of frame 10, by reinforcing and/or stiffening tubular member 18, particularly with respect to twisting forces.
Rectangular member 20 may include any suitable size and shape, particularly to compliment and/or mate with tubular member 18. As shown in
Rectangular member 20 may have any of the details and/or characteristics discussed above with respect to members of frame 10. A cross section of rectangular member 20 may have a width of about 11 mm and a height of about 50 mm, according to certain embodiments of this invention.
Rectangular member 20 may include at least one flange 22 and/or at least one attachment boss 34 along at least a portion of the length, as discussed above with respect to tubular member 18. Rectangular member 20 may include one or more extending lips, projections and/or ridges from the cross section, for example, to aid in attaching or mounting rectangular member 20 to structure 16. Rectangular member 20 may be used along a width of solar panel 12, such as to form butt joint 38 with tubular member 18, as discussed above.
According to certain embodiments of this invention and as shown in
According to certain embodiments of this invention, connection channel 40 prevents axial rotation of anchor 44 with respect to frame 10. Rotation can be prevented with the shape of connection channel 40, for example, with walls 42 to stop a head of a hex bolt from turning in connection channel 40 and eliminate the need for a wrench to hold the bolt head.
Anchor 44 may include any of the objects or materials described above with respect to fastener 36 and/or may include profiled shapes specially adapted to a particular outline of connection channel 40. According to certain embodiments of this invention, anchor 44 includes stainless steel or any other suitable corrosion resistant material.
This invention further may include one or more mounting rails 48. Mounting rails 48 may include any suitable size and/or shape, such as for example, a box, a channel, a tube, a bar and/or any other suitable attaching form. According to certain embodiments of this invention and as shown in
Frame 10 of solar module 14 may include one or more end caps 64 or corner pieces, as shown in
According to certain embodiments of this invention end caps 64 can be pushed or inserted at least partially into both sides of the end frame 10, such as rectangular member 20 at butt joint 38. Typically, end caps 64 lessen or remove sharp corners, hide fasteners 36, and improve aesthetics, such as maintaining groove 98 around solar module 14.
A plurality of or multiple solar panels 14 may be mounted to structure 16 in any suitable number or arrangement to form array 46. Array 46 may include solar modules 14 disposed upon mounting rails 48. Generally, a design of array 46 may seek to maximize a number of solar modules 14 on a structure 16. Solar modules 14 may be abutted next to each other expect for thermal expansion and/or draining tolerances. Alternately, spaces or gaps may remain between solar modules 14, such as to allow personnel access across a roof. Often, but not necessarily, array 46 of solar modules 14 can be mounted in a grid of row and/or columns, such as on a roof.
As shown in
Solar modules 14 can be placed or mounted lengthwise and/or widthwise across mounting rails 48 and frame 10 to anchor mounting rails 48 with anchor 44. According to certain embodiments of this invention, end mount orientation 50 supports solar modules along the width or the shorter side resulting in a span of the length of solar module 14. End mount orientation 50, for example, may include attaching at tubular member 18 or rectangular member 20 by overlapping lengthwise with mounting rail 48.
Alternately, an intermediate mount 52 or middle mount configuration is also shown in
According to certain embodiments of this invention and as shown in
This invention also relates to a method of mounting solar modules 14 with frame 10 having connection channel 40 to structure 16. The method includes sliding, inserting, moving along, and/or engaging at least a portion of anchor 44 into connection channel 40 and tightening, securing, connecting and/or any other suitable action to affix or dispose frame 10 to structure 16.
According to certain embodiments of this invention and as shown in
When referring to the dimensions, shapes, and relative orientations, such as the angles, of the portions of extruded member 68 with reference to
Extruded member 68 may include first linear portion 70 having a length, a first end and a second end. First linear portion 70 may extend vertically, generally vertically and/or substantially vertically.
Extruded member 68 may further include, second linear portion 72 having a length, a first end and a second end where the first end of second linear portion 72 may extend perpendicular, generally perpendicular and/or substantially perpendicular from the second end of first linear portion 70 and may have a length about one eighth to about one half the length of first linear portion 70. According to certain embodiments of this invention, the length of second linear portion 72 may be about one fifth the length of first linear portion 70.
Third linear portion 74 may have a length, a first end and a second end where the first end of third linear portion 74 can extend perpendicular, generally perpendicular and/or substantially perpendicular from first linear portion 70 and in the same direction as second linear portion 72 at a point on first linear portion 70 about a thickness of solar panel 12 below second linear portion 72. Third linear portion 74 may have a length about the same length or different as second linear portion 72.
Extruded member 68 may further include fourth linear portion 76 having a length, a first end and a second end where the first end of fourth linear portion 76 can extend from the second end of third linear portion 74 and may form an acute and/or an obtuse interior angle with respect to first linear portion 70 and third linear portion 74 and fourth linear portion 76 may have a length about one eighth to about three quarters the length of first linear portion 70. According to a certain embodiments of this invention, fourth linear portion 76 has a length about one half the length of first linear portion 70.
First arc portion 78 may have a length, a first end and a second end where the first end of first arc portion 78 can extend from the second end of fourth linear portion 76 and may curve towards first linear portion 70 until the second end of first arc portion 78 is parallel, generally parallel and/or substantially parallel to first linear portion 70. First arc portion 78 may have a length about one tenth to about three quarters of the length of first linear portion 70. According to certain embodiments of this invention, a length of first arc portion 78 is about one fifth the length of first linear portion 70. The length of first arc portion 78, as shown in
Fifth linear portion 80 may have a length, a first end and a second end where the first end of fifth linear portion 80 can extend from the second end of first arc portion 78 perpendicular, generally perpendicular and/or substantially perpendicular to first linear portion 70 and the second end of fifth linear portion 80 may join a point on first linear portion 70, not shown in
Extruded member 68 may further include sixth linear portion 82 having a length, a first end and a second end where the first end of sixth linear portion 82 may extend from the second end of first arc portion 78 parallel, generally parallel and/or substantially parallel to first linear portion 70 and sixth linear portion 82 may have a length about one tenth to about three quarters the length of first linear portion 70. According to certain embodiments of this invention, a length of sixth linear portion 82 may be about one fifth the length of first linear portion 70.
Seventh linear portion 84 can have a length, a first end and a second end where the first end of seventh linear portion 84 may extend from the second end of sixth linear portion 82 perpendicular, generally perpendicular and/or substantially perpendicular to sixth linear portion 82 and toward first linear portion 70. Seventh linear portion 84 can have a length about one twentieth to about one half of the length of first linear portion 70. According to certain embodiments of this invention, the length of seventh linear portion 84 can be about one tenth the length of first linear portion 70.
Eighth linear portion 86 can have a length, a first end and a second end where the first end of eighth linear portion 86 can extend from the first end of first linear portion 70 perpendicular, generally perpendicular or substantially perpendicular to first linear portion 70 and towards seventh linear portion 84 where eighth linear portion 86 can have a length about one tenth to about one half of the length of first linear portion 70. According to certain embodiments of this invention, eighth linear portion 86 can have a length of about one quarter the length of first linear portion 70.
According to certain embodiments and as shown in
Groove 98 may occur on a generally outward or exterior surface of members of frame 10. Groove 98 may ergonomically assist in a user grabbing or handling frame 10 to reduce slipping. Alternately, groove 98 may be provided for aesthetic, cosmetic, and/or provide manufacturer recognition. Groove 98 may be about 0.5 to about 1.5 mm deep and about 5 mm to about 20 mm wide. According to certain embodiments of this invention, groove 98 is about 1 mm deep and about 12 mm wide.
According to certain embodiments of this invention, solar module 14 exceeds the strength of the conventional design by at least twice and more specifically by more than about 2.6 times. This strength includes resistance to bending or bowing, particularly at the center of an end mount orientation 50. The torsional movement or twisting under load can be improved to reduce possible spreading of frame 10 and failure of solar module 14. The improved strength of frame 10 according to certain embodiments of this invention exceeds the IEC 61215, Second edition standard for wind and snow loadings.
Frame 10, according to certain embodiments of this invention, with extruded member 68, as shown in
Similarly, the overall solar module 14 strength according to certain embodiments of this invention was tested to successfully withstand loads of at least 6240 Pa and thereby exceeded the IEC 61215, Second edition standard of 5400 Pa. The testing of module 14, according to certain embodiments of this invention with extruded member 68 as shown in
While in the foregoing specification this invention has been described in relation to certain preferred embodiments, and many details are set forth for purpose of illustration, it will be apparent to those skilled in the art that this invention is susceptible to additional embodiments and that certain of the details described in this specification and in the claims can be varied considerably without departing from the basic principles of this invention.
U.S. Provisional Patent Application Ser. No. 60/944,863, filed on Jun. 19, 2007, is incorporated herein by reference in its entirety.
This patent application claimed the benefit of U.S. Provisional Patent Application Ser. No. 60/944,863, filed on Jun. 19, 2007.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/US2008/066641 | 6/12/2008 | WO | 00 | 7/19/2010 |
| Number | Date | Country | |
|---|---|---|---|
| 60944863 | Jun 2007 | US |
