The present invention generally relates to structures for providing shade, and, in particular embodiments, relates to extendable and retractable shade structures having cost effective designs for providing shade to large areas. In specific embodiments, the extendable and retractable shade structures include solar cells for generating photovoltaic power.
While shade structures exist, and are provided in many environments, they tend to be rigid, expensive, and permanent or time consuming to erect. This is especially true for shade structures for shading large areas, which tend to take the form of permanent rigid structures, as in, for example, a pavilion constructed out of wood, as might be seen at a public park. The permanent construction of or selective setting up and tearing down of a shade structure increases the cost thereof, making the provision of shade in some areas impractical. Because there are many areas that would benefit from being better shaded, there exists a need in the art for new efficient designs for the provision of shade structures.
Shades for large areas are of particular interest. In sunny areas, motor vehicles sitting out in the sun, for instance, in parking lots, become extremely hot and uncomfortable after a few minutes time, and can remain that way for the first few minutes of operation, until an air conditioner is put to use or until cooling air circulates through open windows. The discomfort of entering a hot vehicle left in the sun is well known to everyone, even in moderate climates. The vehicles become so hot, in fact, that it is well know that pets and children can suffer injury and even death from being left in a car in hot weather. Yet very few parking lots are shaded, due to the cost of the structure that must withstand wind loads of 70 mph winds and higher.
Retractable shade structures, such as awnings, provide a cost-effective, lightweight method of shading small areas. They can be retracted automatically when high wind speed is detected. Retractable awnings have typically been used to extend from the sides of buildings and generally have an extendable limit of less than five meters. They are typically extended from the same side on which they are mounted. To cover large areas with a retractable awning will require that the typical extension distance to be greatly increased, at least by a factor of 2 or 3, and perhaps as much as 5 to 10. A new and novel structure is needed to achieve this.
For larger structures, the tensioning of the shade structure is important, because a shade structure that is not sufficiently taut may be easily damaged or otherwise compromised by weather and wind conditions. Thus, there further exists a need for shade structures that are configured to achieve sufficient tensioning to remain structurally sound in at least moderate weather conditions, although it is envisioned that such shade structures could be beneficially retractable to protect them against more severe conditions.
Of particular interest are retractable awnings that extend from a roll. And as a large retractable awning is extended further from the roll, the need to maintain and control proper tension within the awning fabric becomes more important. There is a need in the art for a novel structure to ensure proper tensioning throughout its extendable range. The longer extension distances also necessitate an automatic retraction ability to prevent damage in high winds. Preferably such retraction could be accomplished without the need for power. There is a need in the art for improved automatic retraction methods for large retractable awnings.
Further, there is a need to cover large areas with solar cells that can generate photovoltaic power. Traditional solar cells have been the rigid crystalline silicon type, which require rigid structures, such as the roofs of buildings, on which to be mounted. Some such structures have been used for parking areas, but the cost of the structure with the cost of the traditional solar cells have been prohibitive.
New solar cells are on the verge of commercialization that can be printed or fabricated inexpensively with roll-to-roll technology onto thin flexible fabrics or polymers. The combination of these low-cost, lightweight flexible solar cells to a low-cost retractable shade structure could provide an economical solution to the mounting energy and global warming problems. Photovoltaic power is widely recognized as one of the most environmentally attractive of all energy sources, but the structures and methods for employing solar cells that produce photovoltaic power have not yet proved viable. Thus, there is a need in the art for a novel structure to electrically connect the solar cells on a large rotatably retractable awning.
In one embodiment, this invention provides a shade structure including a rotatable awning roll, an awning fabric, a cable take-up, a cable, and solar cells on the awning fabric for generating photovoltaic power. The awning fabric has a distal movable end and a fixed end, with the fixed end being connected to the rotatable awning roll. The cable connects between the distal movable end of the awning fabric and the cable take-up, which is operable to extend the awning fabric from a retracted state, in which it is wound about said rotatable awning roll, to an extended state, in which the distal movable end is extended at a distance from the rotatable awning roll, by retaining at least a portion of the cable. The solar cells wind about the rotatable awning roll with the awning fabric.
In another embodiment, this invention provides a shade structure including a rotatable awning roll, an awning fabric, a cable take-up drum, a cable, and a cable guide distanced from said rotatable awning roll. The cable take-up drum is associated with the rotatable awning roll to rotate therewith. The awning fabric has a distal movable end and a fixed end, with the fixed end being connected to the rotatable awning roll. The cable extends from the distal movable end of the awning fabric around the cable guide and back to connection to the cable take-up drum, which is operable to extend the awning fabric from a retracted state, in which it is wound about said rotatable awning roll, to an extended state, in which the distal movable end is extended at a distance from the rotatable awning roll, by retaining at least a portion of the cable. The cable take-up drum rotates with the rotatable awning roll, and the simultaneous rotation of the rotatable awning roll and the cable take-up drum causes the cable to be taken up on the cable take-up drum, at the same time causing the awning fabric to be pulled off of the rotatable awning roll toward its extended state.
In embodiments including multiple awning fabrics, this invention provides a shade structure including first and second shade supports in spaced relation to one another. The first shade support includes a first shade roll, having a first rotatable awning roll, and a second cable take-up. The second shade support structure includes a second shade roll, having a second rotatable awning roll, and a first cable take-up. The first shade support includes a first awning fabric having a distal movable end and a fixed end, the fixed end being connected to the first rotatable awning roll such that the first awning fabric is movable between a retracted state in which it is wound about the first rotatable awning roll and an extended state in which the distal movable end is extended at a distance from the first rotatable awning roll. The second shade support includes a second awning fabric having a distal movable end and a fixed end, the fixed end being connected to the second rotatable awning roll such that the second awning fabric is movable between a retracted state in which it is wound about the second rotatable awning roll and an extended state in which the distal movable end is extended at a distance from the second rotatable awning roll. A first cable connects between the distal movable end of the first awning fabric and the first cable take-up, which is operable to extend the first awning fabric from the retracted state to the extended state by retaining at least a portion of the first cable. A second cable connects between the distal movable end of the second awning fabric and the second cable take-up, which is operable to extend the second awning fabric from the retracted state to the extended state by retaining at least a portion of the second cable.
In a more particular embodiment including multiple awning fabrics as above, the cable take-ups are take-ups drums, the second cable take-up drum is associated with the first rotatable awning roll to rotate therewith, and the first cable take-up drum is associated with the second rotatable awning roll to rotate therewith, such that the simultaneous rotation of the first rotatable awning roll and the second cable take-up drum causes the second cable to be taken up on the second cable take-up drum, at the same time causing the second awning fabric to be pulled off of the second rotatable awning roll toward its extended state, and causes the first cable to be taken up on the first cable take-up drum, at the same time causing the first awning fabric to be pulled off of the first rotatable awning roll toward its extended state.
The present invention provides shade structures that will be useful for covering significant surface area. This invention is focused upon, but not particularly limited to providing shade structures that have flexible solar cells incorporated into the shade fabric to generate photovoltaic power. As used herein, “solar cells” are to be understood as encompassing any device capable of receiving light and converting it to useful electric current, including those devices currently known and those to be produced in the future. While endeavoring to provide photovoltaic shade structures that provide photovoltaic power, it was deemed necessary to provide shade structures that can be efficiently constructed, erected, and maintained in order that the costs associated with the photovoltaic shade structure would not exceed the value of the potential for generating photovoltaic power. It is believed that these shade structures will be desirable even without the potential for creating photovoltaic power, and, therefore, useful shade structures are disclosed herein both with and without solar cells, although it should be appreciated that every shade structure disclosed herein could include solar cells and other appropriate associated elements. It was also found to be necessary to have sufficient tension in the shade material itself, as the shade must be capable of withstanding significant wind forces. Shade structures for producing photovoltaic power also must be able to respond to weather conditions to retract when sufficient sunlight is not available, and retract when weather conditions threaten the structural integrity or function of the shade structure.
With reference to
A single shade structure 10A includes a rotatable awning roll 12A carried by a support 14A on posts 16A. Rotatable awning roll 12A carries an awning fabric 18A having a distal end 20A and a fixed end 22A. Fixed end 22A is connected to rotatable awning roll 12A, which, as its name implies, is able to rotate such that awning fabric 18A may move between a retracted state, wherein it is wound about rotatable awning roll 12A, and an extended state, wherein distal end 20A is extended at a distance from rotatable awning roll 12A. A cable 24A is connected between distal end 20A and a cable take-up 26A. Cable take-up 26A, as its name implies, is selectively operable to take in cable 24A to extend awning fabric 18A to the extended state shown in
With reference to
Shade structure 10B is shown as having generic awning fabric 18B that simply serves to block light. But in preferred embodiments, the awning fabrics include solar cells. Thus, awning fabric 18A is shown as including solar cells in the exploded view of a portion of fixed end 22A and awning roll 12A provided in
At awning roll 12A, primary wire 28 communicates with a slip ring 30 for carrying current generated by solar cells 24. Slip rings 30 are commonly used to transfer electric current between a rotating member and a stationary member such as in cable reels, generators, motors, etc. with individual rings for positive and negative and optionally for ground. The rings may be oriented radially or axially as is well known in the art. In a known manner, slip ring 30 communicates with positive and negative primary wires 29, 28 through carbon brushes to which stationary wiring 33 is attached to carry current to an appropriate location. In
In a particular embodiment, solar cells 24 are the flexible thin film type that are presently made in small sizes for providing power to portable devices. Such solar cells are presently made by Iowa Thin Film of Ames, Iowa. Currently, several companies are on the verge of commercializing larger low-cost flexible thin film solar cells using roll-to-roll printing or coating processes onto flexible polymer materials. This includes titanium dioxide based solar cells presently being introduced by Konarka of Lowell, Mass. (www.Konarka.com), and Solar Ply™ solar cells being introduced by Nanosolar of Palo Alto, Calif. (www.nanosolar.com). These flexible thin film type solar cells 24 would typically consist of multiple individual solar cells that are printed or coated onto a polymer film. Each individual solar cell would output very little voltage and current, thus multiple cells would be arranged on panels (like axial sections 36). In such panels (sections 36), the cells would be arranged in series, to multiply the voltage of each cell, and in parallel, to multiply the current of the cells to the limits of the conductors that can be imprinted or coated on the solar cell panel. These conductors would attach to the secondary wires 26 and 27 in multiple places on each solar cell section 36.
Shade structure 10B is shown without solar cells, and awning fabric 18B includes open mesh areas 21B that run axially relative to awning roll 12B in
Two side-by-side shade structures are shown in
Although not limited to any size constraints, it is envisioned that awning rolls of from 3 to 30 meters (m) in axial length will be desirable, especially for the incorporation of solar cells and the potential for generating photovoltaic power. Preferably, the awning rolls will range in length from about 4 to about 20 m, and, more preferably, from 5 to 15 m. This is generally the width of the fixed end of an awning fabric. Although not limited to triangular structures, the awning fabrics preferably have side edges that extend from the distal end fixed to the awning roll at an angle of from about 45 to about 89°. More preferably, the angle is from 50 to 87°, and, in particularly preferred embodiments, from 65 to 85°. As will be seen, particularly preferred are triangular or trapezoidal in shape, and the extendable length of the fabrics may range from about 3 to 50 m, more preferably from 4 to 35 m, and, in particular embodiments, from 5 to 20 m. Within these size ranges, individual awning fabrics are large enough to cover from about 10 to about 1000 m2, more preferably, from 15 to 600 m2, and, in particular embodiments, from 25 to 300 m2. It will be appreciated that, at these preferred sizes, suitable torsional springs for mounting the awning roll could be vary expensive, particularly in embodiments such as that in
Referring now to
Referring to
In another embodiment, a closed system shade structure is provided, allowing for the use of an alternative means of tensioning, allowing for the use of a less expensive torsional spring in the awning roll (or between the awning roll and a cable take-up, as will be disclosed with reference to
In one embodiment, the length of cable 124 taken up by cable take-up 126 is substantially the same as the length of awning fabric 118 unwound from rotatable awning roll 112, such that substantially consistent tension is maintained in awning fabric 118 during extension and retraction thereof. In the exploded partial cross-sectional view of
By driving both rotatable awning roll 112 and cable take-up 126 at the same time, the amount of power required to extend and retain awning fabric 118 extended is substantially reduced over an embodiment in accordance with
In another embodiment, it is desirable that the tension in the awning fabric 118 increase as it is extended, and thus, the length of cable 124 wound on cable take-up 126 is greater than the length of awning fabric 118 unwound from rotatable awning roll 112. This could be achieved, for example, by having a drum 126′ with a large end 160 larger than the diameter provided by awing fabric 112 when retracted on the awning roll 112 and small end 162 larger than the diameter provided by awning roll 112 when awning fabric 118 is fully extended, with the contour of drum 126′ being such that the position of cable 124 on drum 126′ is at a greater radial distance from the center of rotation of drum 126′ than is the position of fabric 118 on awning roll 112 relative to the center of rotation of awning roll 112. In such a closed system, the forces resulting from the tension in the extended system and acting on awning roll 112 are equal to the forces action on drum 126′, and, because these forces act at a greater radial distance from the center of rotation of drum 126′ than the distance that they act on awning roll 112 relative to the center of rotation thereof, the system will self-retract when any braking force serving to keep it extended is removed as the moment arm of the drum 126′ is larger than the moment arm of the roll 112. Such self-retraction can be achieved without the inner spindle/torsional spring configuration of
The closed system concept is next expanded to cover a duplex structure in which a single drive can extend two awning fabrics from two awning rolls. Referring now to
This type of closed system can be achieved in many ways, and this invention is not limited to or by any particular manner of winding cables and fabrics on their respective cable take-ups or awning rolls. However, in a particularly preferred embodiment awning roll 212A and cable take-up 226B are associated to rotate in the same direction, as are awning roll 212B and cable take-up 226A. Awning fabric 218A winds around awning roll 212A in one direction, and cable 224B winds around cable take-up drum in the opposite direction. Awning fabric 218B winds around rotatable awning roll 212B in one direction, and cable 224A winds around cable take-up 226A in the opposite direction. Thus, when any one of the rotatable elements of this system is driven, the other rotatable elements are driven, and, due to the manner in which cables and fabric wind on these elements, the entire system extends or retracts together. A major advantage of the duplex system is that the force of the wind blowing on one awning fabric to extend it will act on the other awning fabric to retract it, such that there will be little or no tendency for extension or retraction of the closed system.
Similar to the embodiments of structure 110, the length of cables 224A, 224B taken up by cable take-ups 226A, 226B may be substantially the same as the length of awning fabrics 218A, 218B unwound from rotatable awning rolls 212A, 212B, such that substantially consistent tension is maintained in the entire system, or, alternatively, the length of cables 224A, 224B taken up by cable take-ups 226A, 226B may be slightly larger than the length of fabrics 218A, 218B unwound from rotatable awning rolls 212A, 212B, such that tension increases in the system as it is extended. The same drum take-up concepts and others may be applied.
As with shade structure 110, this duplex system achieves low power extension. If awning rolls 212A, 21B are configured with an inner stationary spindle and torsional spring (as with spindle 13A and spring 30A, discussed above) a controlled retraction is possible upon release of an appropriate drive and clutch mechanism. If the system is configured as in the disclosure of
In
Referring now to
Throughout this disclosure, various shade structures have been disclosed. It should be appreciated that aspects of one shade disclosure might be incorporated into the structure of another shade disclosure inasmuch as each independent aspect and how it might be applied in a different structure would be readily appreciated by those of ordinary skill in the art. For example, solar cells may be practiced with any embodiment, although they were specifically disclosed with respect to the embodiment of
In light of the foregoing, it should thus be evident that this invention provides many novel features in a shade structure, and, substantially improves the art. While, in accordance with the patent statutes, only the preferred embodiments of the present invention have been described in detail hereinabove, the present invention is not to be limited thereto or thereby. Rather, the scope of the invention shall include all modifications and variations that fall within the scope of the attached claims.
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Number | Date | Country |
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Number | Date | Country | |
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20060090858 A1 | May 2006 | US |