SYSTEMS AND METHODS OF GENERATING ENERGY FROM SOLAR RADIATION
A solar reflector assembly is provided for generating energy from solar radiation. The solar reflector assembly is configured to be deployed on a supporting body of liquid and to reflect solar radiation to a solar collector. A solar reflector assembly comprises an inflatable elongated tube having an upper portion formed at least partially of flexible material and a lower ballast portion formed at least partially of flexible material. A reflective sheet is coupled to a wall of the tube to reflect solar radiation. The elongated tube has an axis of rotation oriented generally parallel to a surface of a supporting body of liquid.
Latest Combined Power LLC Patents:
This application is a continuation of and claims priority to U.S. patent application Ser. No. 12/849,761, filed Aug. 3, 2010, which is incorporated by reference herein in its entirety, which is a non-provisional of and claims priority to U.S. patent application Ser. No. 61/231,081, filed Aug. 4, 2009, 61/233,667, filed Aug. 13, 2009, and 61/244,349, filed Sep. 21, 2009, each of which is incorporated by reference herein in its entirety.
FIELD OF THE DISCLOSUREThe present disclosure relates to solar energy systems.
BACKGROUND OF THE DISCLOSUREThere has been a long-standing need to provide energy generation from renewable sources. Various renewable energy sources have been pursued, such as solar energy, wind, geothermal, and biomass for biofuels as well as others.
Solar radiation has long been a prime candidate for fulfilling this need. Various approaches have been taken to achieve energy generation from solar radiation. To that end, much focus has been directed to creating a low cost solar energy conversion system that functions with high efficiency and requires little maintenance.
For example, solar panels formed of photovoltaic cells (solar cells) are used to transform light to electricity. Such systems have been implemented in various applications. Solar panels have been generally effective for small-scale electrical generation, such as powering small electronics, electrical generation for residential applications, and electrical generation for space-based systems. However, current solar panel technology has been ineffective for large-scale uses, such as electrical generation sufficient for municipal applications. The costs associated with such large-scale usages have been prohibitive. Current solar panels are relatively expensive and do not allow cost-effective energy storage.
Other approaches include concentrating solar radiation on solar collectors for energy generation, commonly referred to as concentrated solar power (CSP). CSP systems typically use reflective surfaces to concentrate the sun's energy from a large surface area on to a solar collector. For example, the concentrated solar energy can be used to heat a working fluid. The heated fluid is then used to power a turbine to generate electricity. Alternatively, photovoltaic cells can be used at the solar collector, eliminating the need for numerous, expensive cells. In an effort to maximize efficiency, the reflective surfaces of CSP systems can be coupled to a device that tracks the sun's movement, maintaining a focus on a receiver target throughout the day. Using this approach, the CSP system can optimize the level of solar radiation directed towards the solar collector.
Although such CSP systems are better than traditional flat-panel photovoltaic cells for large-scale applications, shortfalls exist. For example, glass and metal reflector assemblies are expensive to manufacture, ship and install. Further, current tracking devices used with CSP can be relatively expensive and complicated. As a result, current approaches have yet to achieve significant market penetration because of cost issues.
Biomass production, such as algae and other microorganisms, has increasingly been of interest. The potential usage of such material is found across a wide range of applications, including biofuel feedstock production, fertilizer, nutritional supplements, pollution control, and other uses.
Current approaches for biomass production include “closed-air” systems that contain biomass production within a controlled environment, limiting exposure to outside air. Examples of such systems include closed photo-bioreactor structures forming a closed container for housing a culture medium for generating biomass. Having a controlled environment helps maximize the generation of algal material by limiting exposure to invasive species as well as controlling other environmental factors that promote algal growth. Closed-air systems significantly reduce evaporation and therefore significantly reduce demands on water resources. In addition, closed-air systems facilitate the sequestration of carbon dioxide gas, which promotes algal growth, facilities compliance with environmental regulations, and, according to a large number of scientists, benefits the environment generally. However, such systems can be expensive and, in many instances, cost prohibitive.
It should be appreciated that there remains a need for a system and method of generating energy from solar radiation in a low-cost, large-scale manner. There also exists a need for a closed-air photo-bioreactor to promote algal growth in a low-cost, large-scale manner. The present disclosure fulfills these needs and others.
SUMMARY OF THE DISCLOSUREIn general terms, the present disclosure provides a solar reflector assembly useable for generating energy from solar radiation. Embodiments of the solar reflector assemblies are inflatable elongated tubes of flexible material with each tube including a reflective sheet to reflect solar radiation to a solar collector. This structure and the materials employed provide significant cost savings for manufacture, shipping and deployment of the solar reflector assemblies. The solar reflector assembly is configured to be deployed on a supporting body of liquid. This provides both liquid ballasting capability and structural support. Beneficially, the solar reflector assemblies are inexpensive to manufacture, deploy and operate, providing a cost effective solution for energy generation.
Exemplary embodiments of a solar reflector assembly includes an inflatable elongated tube having an upper portion formed at least partially of a flexible material and a lower ballast portion formed at least partially of a flexible material. The lower ballast portion may define a reservoir containing fluid facilitating ballast. The elongated tube has an axis of rotation oriented generally parallel to a surface of a supporting body of liquid and a reflective sheet coupled to a wall of the tube to reflect solar radiation towards the solar collector. The reflective sheet may be coupled to either an interior wall or an exterior wall of the elongated tube. The fluid facilitating ballast has a top surface that is generally parallel to a surface of a supporting body of liquid.
In exemplary embodiments, the reflective sheet can be configured to reflect substantially all solar radiation towards the solar collector. In another exemplary embodiment, the reflective sheet can be configured to substantially reflect a first prescribed wavelength range towards a solar collector and to substantially transmit a second prescribed wavelength range therethrough. In the case of an interior reflective sheet, the reflective sheet may also facilitate equilibrium of pressure on its opposing sides. One end cap assembly may be coupled to the elongated tube, or a pair of end cap assemblies can be coupled to the elongated tube, in which at least one of the end cap assemblies is configured to facilitate the flow of gas and/or liquid into and out of the elongated tube to maintain pressure within the tube. The upper portion formed of thin-gauge, flexible material allows solar radiation to pass through for reflection by the reflective sheet.
Inflatable supports can be disposed on the exterior wall of the tube to maintain the reflective sheet in a prescribed orientation. For example, the reflective sheet can be disposed to have various cross sectional shapes, including flat, v-shaped, u-shaped, or parabolic, among others, as desired. A pair of supports can be used, coupled to longitudinal sides of the reflective sheet.
In a detailed aspect of an exemplary embodiment, the reflective sheet is formed as a hot mirror, configured to reflect infrared (IR) radiation (e.g., heat reflective) while allowing visible light to pass through (e.g., visibly transparent), across wide angles of incidence. For example, the reflective sheet allows transmittance of at least 50 percent of incident energy in the wavelength band between about 400 nm and 700 nm at normal incidence. In a detailed aspect of an exemplary embodiment, the reflective sheet allows transmittance of at least 90 percent of incident energy in the wavelength band between about 400 nm and 700 nm at normal incidence.
In another detailed aspect of selected exemplary embodiments, the reflective sheet can have a high percentage of reflection for substantially all incident solar IR radiation above about 700 nm or, in other embodiments, above about 750 nm. In yet other embodiments, the reflective sheet can be configured to have a high percentage of reflection within a bounded range of IR wavelengths. Exemplary ranges include 700-1200 nm, 700-2000 nm, 750-1200 nm, and 750-2000 nm, among others. It should be appreciated that other ranges can be used.
More particularly, by example and not limitation, a system for generating energy from solar radiation is provided, comprising a pool housing a supporting body of liquid and one or more solar reflector assemblies disposed on the supporting body of liquid. Each solar reflector assembly includes an inflatable elongated tube having an upper portion formed at least partially of flexible material, a lower ballast portion formed at least partially of flexible material and an axis of rotation oriented generally parallel to a surface of the supporting body of liquid, and a reflective sheet coupled to a wall of the tube to reflect solar radiation towards a solar collector. The reflective sheet may be coupled to an interior wall of the elongated tube such that the upper portion and the lower ballast portion are separated by the reflective sheet. Alternatively, the reflective sheet may be coupled to an exterior wall of the elongated tube.
The reflective sheet may be coupled to the elongated tube in a manner to provide a pressure differential between opposing sides of the reflective sheet such that the reflective sheet can be given a prescribed shape to facilitate reflection of solar radiation towards the solar collector. The solar reflector assembly may facilitate equilibrium of pressure on opposing sides of the reflective sheet. The lower ballast portion of the elongated tube contains liquid facilitating ballast. The liquid facilitating ballast has a top surface that is generally parallel to the surface of the supporting body of liquid. The system further includes a solar collector positioned to receive reflected solar radiation from the reflective sheet.
Embodiments of the system for generating energy from solar radiation may further comprise an electrical generator assembly operatively coupled to the solar collector to convert the reflected solar radiation to electricity. At least one end cap assembly can be coupled to an elongated tube, and a pair of end cap assemblies can be coupled to opposing ends of the one or more elongated tubes, in which at least one of the end cap assemblies is configured to facilitate the flow of gas and/or liquid into and out of the elongated tube to maintain pressure within the tube. A rotation assembly may be coupled to an elongated tube at any location on the tube. In exemplary embodiments, a rotation assembly is coupled to at least one of the end cap assemblies to induce controlled rotation of the elongated tubes to direct the reflected solar radiation to the solar collector.
In an exemplary embodiment, the reflective sheet is coupled to the elongated tube in a manner to provide a pressure differential between opposing sides of the reflective sheet such that the reflective sheet can be given a prescribed shape to facilitate reflection of solar radiation towards the solar collector. Alternatively, the reflective sheet can be configured to be taut when the elongated tube is inflated to form a generally planar shape. In yet another embodiment, the reflective sheet can be configured to hang between spaced-apart portions of the internal wall of the tube to form a generally catenary shape.
In an exemplary embodiment, the elongated tube defines an elongated reservoir extending the length of the tube for passing a heat-transfer fluid therethrough, the elongated reservoir positioned above the reflective sheet such that solar radiation reflected by the reflective sheet is directed towards the elongated reservoir. The elongated tube can further define a plurality of elongated reservoirs positioned above the reflective sheet, defining multiple focal areas of reflected radiation present at different angles of incident solar radiation. In this manner, the solar collector can be coupled to the tube, through which a heat-transfer fluid can pass to absorb the reflected radiation, and then be used to power electricity generation.
In exemplary embodiments, the solar reflector assembly may comprise one or more pass-through fittings coupled to the elongated tube to facilitate the flow of gas and liquid into and out of the elongated tube.
In a detailed example of an exemplary embodiment, the solar reflector assembly or system can include a rotation assembly coupled to at least one end of the elongate tube and configured to rotate the elongated tube such that the reflective sheet directs solar radiation towards the solar collector throughout the day. In one approach, the rotation assembly can include a plurality of gas bladders coupled to the elongated tube, in which the rotation assembly is configured to adjust the content of gas bladders to rotate the elongated tube. In another approach, the rotation assembly is coupled to at least one end of the elongated tube to induce controlled rotation of the elongated tube to direct the reflected solar radiation towards the solar collector.
In another exemplary embodiment, a plurality of elongated tubes are coupled together along longitudinal sides, forming a raft, in which a reflective sheet is disposed either within or atop each tube. The tubes can further include one or more reservoirs for passing heat-transfer fluid through. Alternatively, an external solar collector can be disposed in a prescribed location, spaced apart from an elongated tube or from the raft of elongated tubes to receive reflected solar radiation from the reflective sheets.
The elongated tube may further comprise a culture medium for photosynthetic biomass, thus forming a combined solar reflector and photobioreactor assembly (“CSP/PBR”). The culture medium housed in the tube can be used, e.g., to facilitate photosynthetic biomass growth, such as algal biomass. The reflective sheet may be configured to substantially reflect a first prescribed wavelength range towards a solar collector and to substantially transmit a second prescribed wavelength range therethrough to the culture medium within the elongated tube. In this manner, a portion of solar energy is directed towards the solar collector, while another portion is utilized by the culture medium, e.g., to facilitate photosynthetic biomass growth, such as algal biomass. The CSP/PBR assemblies may be disposed on a supporting body of liquid and include a solar collector positioned to receive reflected solar radiation from the reflective sheet. Beneficially, this embodiment serves to reduce the heat input, and therefore the cooling load for the biomass production component of such an embodiment.
For purposes of summarizing the disclosure and the advantages achieved over the prior art, certain advantages of the disclosure have been described herein. Of course, it is to be understood that not necessarily all such advantages may be achieved in accordance with any particular embodiment of the disclosure. Thus, for example, those skilled in the art will recognize that the disclosure may be embodied or carried out in a manner that achieves or optimizes one advantage or group of advantages as taught herein without necessarily achieving other advantages as may be taught or suggested herein.
All of these embodiments are intended to be within the scope of the disclosure herein disclosed. These and other embodiments of the present disclosure will become readily apparent to those skilled in the art from the following detailed description of the preferred embodiments having reference to the attached figures, the disclosure not being limited to any particular preferred embodiment disclosed.
Embodiments of the present disclosure will now be described, by way of example only, with reference to the following drawings in which:
With reference now to the drawings, and particularly
More particularly, in exemplary embodiments the elongated tube 12 is a unitary structure that includes lower ballast portion 23, which provides ballast for the solar reflector assembly 10. In other words, lower ballast portion 23 is the lower section of the elongated tube itself and, as such, is integrally formed with the elongated tube 12. This structure is advantageous because it obviates the need for additional components or structural elements to facilitate ballast. It also enables pressure differential or pressure equilibrium between the chambers 21, 23 on either side of the reflective sheet 14, as described in more detail herein. The elongated tubes may include a gas in the upper chamber 21 and a reservoir liquid 20 in the lower chamber 23 to facilitate ballast. As discussed in more detail herein, the reflective sheet could also be coupled to an exterior wall of the tube.
The solar reflectors are supported by a body of liquid 16 and are configured to rotate to direct reflected solar radiation towards a solar collector 18. The solar reflectors are used to reflect solar radiation towards a solar collector 18 configured to transform the solar energy to electricity or process heat. Beneficially, the solar reflector assemblies are inexpensive to manufacture and operate, providing a cost effective solution for electrical generation or process heat from solar energy.
Each tube 12 is formed of transparent, lightweight flexible plastic optionally coupled at each end to rigid end cap assemblies 24, which facilitate the flow of liquid and gas into and out of the tubes. Positive pressure within the tube keeps them rigid and maintains the tube in a generally cylindrical configuration having a substantially constant cross section along the length of the tube. The tube is set on an expanse of liquid 16 in a pool 19 and includes a reservoir of fluid 20 to facilitate ballast of the tube and maintain buoyancy in a prescribed manner to best track the sun, as described herein. The tubes 12 will float at a level such that the liquid level within the tube is generally even or parallel with the level of liquid 16 on which the tube is floating. More specifically, in operation the top surface of the ballast liquid is substantially parallel to the top surface of the supporting body of liquid. However, the level of liquid within the tube can vary, from empty to full with liquid, as desired.
The tubes 12 are configured in an elongated cylindrical configuration. In exemplary embodiments, the tubes are formed of a single sheet of a thin gauge, flexible material, which can be various plastics such as polyethylene, having a thickness between about 50 microns (2 mil) and 300 microns (12 mil). In other embodiments, tubes can be formed of multiple layers and multiple sections of material. In addition, other lightweight, flexible materials or combinations of materials can be used. Tubes of various sizes can be used, to include tube diameter and tube length, without departing from the disclosure. In the present embodiment, the entire tube is formed of transparent material; however, it is sufficient if an upper portion of the tube is transparent to enable solar radiation to be directed towards the reflective sheet.
The tubes can be susceptible to deterioration over time as result of exposure to solar radiation. For example, polyethylene can be susceptible to UV-B radiation, and other materials may be susceptible to other ranges of radiation. The tubes can be protected from premature deterioration using systems and methods as disclosed in the present inventor's co-pending application, U.S. appl. Ser. No. 12/253,962, filed Oct. 18, 2008, entitled “System and Method for Protecting Enclosure from Solar Radiation,” which is incorporated by reference herein for all purposes.
With reference now to
The reflective sheet 14 can be coupled to the elongated tube 12 to enable a pressure differential to be maintained on opposing sides of the sheet. The pressure differential can be used to form the reflective sheet to a prescribed shape. For example, a higher pressure can be maintained on the upper surface of the reflective sheet such that the reflective sheet has a curved or, more preferably, a generally parabolic shape. Alternatively, the solar reflector assembly can be configured to maintain pressure equilibrium on both sides of the reflective sheet to facilitate other desired shapes for the reflective sheet. For example, the one or more end caps can be configured to allow gas to move between the upper portion and lower ballast portion of the tubes by coupling a pass-through to the upper chamber with a pass-through to the lower chamber. As discussed in more detail below, the reflective sheet can be configured to assume any number of different shapes without departing from the disclosure.
In an exemplary method of manufacture, a sheet of reflective material is attached along longitudinal side edges to a first side of a sheet of tube material at a prescribed distance from each other. Opposing longitudinal side edges of the tube material are attached to each other forming a cylinder with the reflective material disposed within the interior of the tube. The distance between the edges of the reflective material is selected to form a prescribed shape for the reflective sheet, when in use.
With reference again to
Each end cap assembly 24 is configured to facilitate flow of gas and liquid to and from the interior of the elongated tube 12. To that end, end cap assembly 26 may include liquid transfer tubes 32 and gas transfer tubes 34 that extend from the end caps. Liquid can be injected or withdrawn through liquid transfer tubes to regulate how high the elongated tubes 12 float in the support liquid 16. Similarly, gas can be injected or withdrawn through gas transfer tubes. The inlets and outlets pass through pipes 36, which also serve as axles on which end-caps rotate. By passing through the axis of rotation of the end-caps, the liquid and gas transfer tubes can thus be permanently interfaced to the elongated tube 12 and can allow fluid and gas transfer while the elongated tube is turning. However, other inlets and outlets passing through both, eccentrically mounted control valves on the end-cap, or valves mounted on the plastic tubing itself are possible in other embodiments without departing from this disclosure.
In exemplary embodiments, the liquid transfer tubes 32 are submerged within the liquid 20 within the tube. Gas transfer tubes 34 are disposed above the liquid. In other embodiments, various other configurations can be used. One liquid and one gas transfer tube passing through each end-cap are used. It is also possible to have more than two transfer tubes passing through each end-cap. In exemplary embodiments, the rotation element includes sealed ball bearings, which enable long life of the assembly despite potential prolonged exposure to moisture. There are multiple methods possible for sealing the ends of the tubes.
The solar energy collection system can include an array of solar reflector assemblies configured to reflect solar radiation towards multiple solar collectors. For example, the system can include groupings of solar reflectors disposed on opposing sides of linear solar collectors, and the solar reflectors can be directed to the closest solar collector.
With reference now to
In exemplary embodiments, the heat-transfer reservoir 142 is attached to or formed in the wall of the elongated tube from the same polymer material. For example, an exterior and an interior sheet of polymer material can be used together by spaced apart, generally parallel seams to form the heat-transfer reservoir. The material for the heat-transfer reservoir should have sufficient strength and durability characteristics to handle the anticipated pressure, heat, and so on, when the heat-transfer fluid is heated.
In other embodiments, the heat-transfer reservoir can include additional structure and/or other materials, to facilitate the use of selected heat-transfer fluids that achieve high pressures and high temperatures. For example, the heat-transfer reservoir as discussed above can further include a rigid tube installed at tube deployment, sandwiched between the exterior and interior sheets and extending between the end cap assemblies.
With reference now to
Use of a plurality of heat transfer reservoirs can be effective in embodiments in which the solar reflector assembly does not rotate to track the sun. Rather, as the sun progresses across the sky, the reflected focal area of the reflective sheet will track across the plurality of heat transfer reservoirs. The system can be configured to pass the heat-transfer fluid through the appropriate reservoir at prescribed times to coincide with the location of the reflected focal area.
For example, as shown in
With reference now to
With reference now to
Various approaches for manufacture can be used. For example, the tube can be formed by an upper panel and a lower panel, along opposing seams, and the reflective material is disposed therebetween attached at the seam. The tube can also be formed by a single sheet of material to which the reflective sheet is attached. The opposing ends of the sheet can be coupled together forming the tube, having the reflective sheet disposed in the interior. Due to the flexibility of the material it can be rolled up into a compact format for shipping and deployment.
With reference now to
Turning to
Supports 525 are disposed on an exterior side 517 of the tube 512. The longitudinal sides of the reflective sheet 514 are coupled to the supports 525 and an intermediate section of the reflector sheet 514 can be coupled to the tube 512, such that the reflective sheet 514 is generally flat. The elongated tube 512 has an upper portion 521 and a lower ballast portion 523 containing reservoir liquid 520, though the upper and lower ballast portions are not physically separated because of the external location of the reflective sheet 514. In exemplary embodiments, the elongated tube 512 is a unitary structure that includes lower ballast portion 523, which provides ballast for the solar reflector assembly 510. In other words, lower ballast portion 523 is the lower section of the elongated tube itself and, as such, is integrally formed with the elongated tube 512. This structure is advantageous because it obviates the need for additional components or structural elements to facilitate ballast. The elongated tube 512 is made of a thin-gauge, flexible material, as described in more detail above, and, in contrast to other embodiments, need not be transparent because the reflective sheet 514 is externally mounted.
With reference now to
In the exemplary embodiments of
The supports 525 of the exemplary embodiments are independently inflatable relative to each other and the primary tube 512. Alternatively, the supports 525 can be operatively coupled to each other and/or to primary tube 512 to enable air to pass between the components to maintain air pressure therein.
In the exemplary embodiments of
With reference now to
An externally mounted reflector sheet can also be used in embodiments described above in which a plurality of elongated tubes are coupled together along longitudinal sides, forming a raft, as well as with embodiments having gas bladders that extend the length of the tube(s).
Turning to
In each of the forgoing configurations, the reflective sheet can be fully reflective, such as when used for embodiments configured only as a solar reflector. Alternatively, the reflective sheet can be configured as a hot mirror, as disclosed in the U.S. Patent Application Ser. No. 61/233,667, filed Aug. 13, 2009, which is incorporated by reference herein in its entirety, and described herein, for embodiments configured for biomass generation or for a combined solar reflector and photobioreactor assembly (“CSP/PBR assembly”). It should be noted that in exemplary embodiments employing both internal and exterior mounting of the reflective sheet, the tube material is at least partially translucent such that biomass may grow in the ballast fluid in the lower ballast portion of the tube. In addition, biomass may grow in the pools of support liquid. This biomass could be harvested and processed into a useful product
In exemplary embodiments the reservoir of liquid within the tubes can also be used to grow biomass using systems and methods as disclosed in U.S. Patent Application Ser. No. 61/152,949, filed Feb. 16, 2009 (“'949 Application”), which is incorporated by reference herein in its entirety. With reference now to the drawings, and particularly
The reflective sheet is configured to reflect IR radiation towards a solar collector 618, while allowing visible light to pass through to a culture medium 620 within the lower ballast portion 623 of the tube 612. The array is supported by a body of liquid 616 in a pool 619.
The reflective sheet 614 is formed of lightweight flexible reflective material configured to allow prescribed wavelengths of solar radiation to pass through, while reflecting other wavelengths of solar radiation towards the solar collector 618. In exemplary embodiments, the reflective sheet is formed as a hot mirror, configured to reflect IR radiation (e.g., heat reflective) while allowing visible light to pass through (e.g., visibly transparent), across wide angles of incidence. Thus, IR radiation is reflected towards the solar collector, while the visible light passes through to the culture medium 620 to facilitate growth of the biomass, e.g., algal biomass. Moreover, minimizing penetration of IR radiation into the culture medium reduces the heat load of culture, allowing the culture to be maintained at a temperature conducive to optimal biomass growth. It should be noted that in this and other exemplary embodiments some tubes could be deployed with hot mirrors and some with full spectrum reflectors, in order to finely tune the percentage of insolation that makes it into culture to generate biomass, and how much insolation is reflected to the receiver for power generation.
The term “visibly transparent,” unless otherwise specified, is intended to refer to an attribute of the reflective sheet of transmitting a large fraction (e.g., an average of at least 50%) of visible radiation (e.g., at least between about 400 nm to about 700 nm) therethrough. The term “heat reflective,” unless otherwise specified, is an attribute of the reflective sheet of reflecting a large fraction (e.g., an average of at least 50%) of IR radiation (e.g., above 750 nm).
In exemplary embodiments, the reflective sheet 614 comprises a dielectric thin film disposed on a flexible substrate, such as a flexible polymeric sheet. For example, the reflective sheet 614 can include flexible films such as IR reflective films sold under the brand name Prestige™ Series, available from 3M Company. The reflective sheet 614 is further configured to endure a high moisture environment, without significant deterioration. The dielectric film can comprise one or more layers (or stacks) disposed on the substrate. In multi-layer configurations, the thickness of each of the layers can be selected to optimize the properties of the reflective sheet. Moreover, intervening layers having varying properties can be used to optimize performance of the reflective sheet. In other embodiments, the reflective sheet can comprise other materials, known in the art, having sufficient characteristics for use in the intended purposes, such as metal oxides disposed on a substrate. Suitable substrates can include standard contractor-grade low-density polyethylene (LDPE), polyethylene terephthalate (PET) (e.g., uniaxial, biaxial), polyester, polyterephthalate esters, polyethylene naphthalate, polypropylene, and others.
In exemplary embodiments, the reflective sheet 614 is configured to be visibly transparent and heat reflective across a wide range for the angle of incidence of solar radiation, (e.g., 0 degrees to at least 60 degrees). At very high angles of incidence, the reflective sheet may behave more like a full spectrum reflector. As discussed below, the assembly can be configured to rotate to track the sun such that the reflective sheet 614 can be optimized for operation with a tight range for the angle of incidence of solar radiation (e.g., ±20 degrees).
As shown in
The end cap assembly 624 may also comprise eccentrically mounted pass-through fittings 639 instead of transfer tubes, as shown in
With reference now to
In other embodiments, the reflective sheet can be configured to varied parameters for reflection and transmission performance. For example, the reflective sheet can be configured to achieve higher levels of transmittance within the visible spectrum, particularly within wavelengths to optimize photosynthesis (e.g., between about 380 nm-420 nm, at the lower end, and about 690 nm-750 nm, at the upper end). In yet other embodiments, the reflective sheet can be configured for high transmission (e.g., above 50 percent) for a range (or ranges) within the visible spectrum, such as, between about 400-500 nm and/or about 600-700 nm. Such ranges can be selected based on the needs of an algal culture of a prescribed embodiment.
The reflective sheet's performance parameters as a heat reflector can also be varied across embodiments without departing from the disclosure. For example, it is contemplated to configure the reflective sheet to have a high percentage of reflection for substantially all incident solar IR radiation above about 700 nm or, in other embodiments, above about 750 nm. More particularly, the reflective sheet reflects at least 50 percent of incident energy at wavelengths above about 750 nm at normal incidence, and in some instances reflects at least 90 percent of incident energy at wavelengths above about 750 nm at normal incidence. In yet other embodiments, the reflective sheet can be configured to have high percentage of reflection within a bounded range of IR wavelengths. Exemplary ranges include 700-1200 nm, 700-2000 nm, 750-1200 nm, and 750-2000 nm, among others. It should be appreciated that other ranges can be used, to account for performance, location, cost, and other considerations.
With reference again to
Positive pressure within the tube maintains the tube in a substantially rigid, cylindrical configuration. In addition to growing biomass, the culture medium within the tube facilitates ballast of the tube on the supporting liquid 616 in pool 619. The tube will float such that the top surface of the liquid within the tube is generally parallel with the surface of liquid on which the tube is floating. The level of liquid within the tube can vary, from empty to fully filled with liquid, as desired. The system may be further configured to extract biomass from within the CSP/PBR assemblies for processing. Various approaches can be used for this purpose. For example, the present inventor's co-pending ‘949 application, entitled “System for Concentrating Biological Culture and Circulating Biological Culture and Process Fluid,” which is incorporated by reference herein for all purposes, discloses effective approaches towards that end.
It should be noted that any of the above-described solar reflector assembly and system embodiments could be modified to incorporate a culture medium to provide different embodiments of a CSP/PBR assembly. For instance, the elongated tube of the CSP/PBR assembly can be configured to achieve various different cross-sectional shapes, as depicted in
In addition, as with the solar reflector assemblies discussed above with reference to
Turning to
The “triple panel” solar reflector assemblies can be arranged in an array configuration, as shown in
Turning to
The reflective sheet 1014 is slightly shorter than the characteristic chord length, thus pulling in the sides of the circles at the attachment points A. In the case of modest internal pressure that is equal on both sides of the panel, this advantageously guarantees that the panel is flat, even in the case of modest irregularities introduced in manufacturing. The lower ballast portions 1023a, 1023b together remain largely cylindrical. Holes 1047 defined in the second panel 1045 facilitate the equalization of the level of ballast within the tube during rotation. As shown in
Rotation of the tube 1112 is accomplished by a rotation assembly that includes a strap 1149 and a stabilizer 1151. In this embodiment, the strap is coupled to the tube 1112 by being wrapped 1147 around the tube, but other means of coupling a rotation assembly to the tube are possible. The tube 1112 is rotated by pulling the strap 1149 in the direction corresponding to the desired turning direction for the tube 1112. Stabilizer 1151 with stabilizer rods 1143 prevents lateral movement of the tube when strap 1149 is pulled, thereby inducing rotation as opposed to translation. It will be appreciated that a rotation assembly can be placed anywhere along the length of the tube, and that multiple different means, including end-caps, axles, straps and other means can be employed simultaneously to impart rotation on the tube.
It should be noted that exemplary embodiments described herein can be controlled by a computer. Either an open loop system that is pre-programmed with the position of the sun in the sky or a closed loop system that has a sensor or sensors that detect the position of the sun in the sky or a combination of these two strategies can be used to control the position of the tubes.
Thus, it is seen that systems and methods of generating energy from solar radiation are provided. It should be understood that any of the foregoing configurations and specialized components or chemical compounds may be interchangeably used with any of the systems of the preceding embodiments. Although exemplary embodiments of the present disclosure are described hereinabove, it will be evident to one skilled in the art that various changes and modifications may be made therein without departing from the disclosure. It is intended in the appended claims to cover all such changes and modifications that fall within the true spirit and scope of the disclosure.
Claims
1. A solar reflector assembly comprising:
- a primary inflatable elongated tube having an upper portion formed at least partially of flexible material and a lower ballast portion formed at least partially of flexible material; and
- a reflective sheet coupled to an exterior wall of the upper portion of the primary tube to reflect solar radiation;
- wherein the primary tube has an axis of rotation oriented generally parallel to a surface of a supporting body of liquid.
2. The solar reflector assembly of claim 1 wherein the lower ballast portion defines a reservoir containing liquid facilitating ballast, the liquid having a top surface generally parallel to the surface of the supporting body of liquid.
3. The solar reflector assembly of claim 1 further comprising at least one support component disposed on the exterior wall of the primary tube to support the reflective sheet.
4. The solar reflector assembly of claim 3 wherein pressure from air inside the primary tube compresses the support component such that the reflective sheet maintains a substantially rigid configuration.
5. The solar reflector assembly of claim 3 wherein the at least one support component has a generally circular cross section.
6. The solar reflector assembly of claim 1 wherein the at least one support component is a secondary inflatable tube.
7. The solar reflector assembly of claim 6 wherein the at least one support component includes two support components.
8. The solar reflector assembly of claim 7 wherein the two support components are independently inflatable.
9. The solar reflector assembly of claim 7 wherein the two support components are operatively coupled to each other to enable air to pass between the two support components.
10. The solar reflector assembly of claim 6 wherein the at least one support component is operatively coupled to the primary tube to enable air to pass between the primary and secondary inflatable tubes.
11. The solar reflector assembly of claim 1 wherein the primary tube further comprises a culture medium for photosynthetic biomass.
13. The solar reflector assembly of claim 3 wherein the at least one support component runs substantially the entire length of the primary tube.
14. The solar reflector assembly of claim 1 further comprising a solar collector spaced apart from the primary tube and positioned to receive reflected solar radiation from the reflective sheet.
15. The solar reflector assembly of claim 1 wherein the reflective sheet substantially reflects a first prescribed wavelength range and substantially transmits a second prescribed wavelength range therethrough.
16. A system for generating energy from solar radiation, comprising:
- a pool housing a supporting body of liquid;
- one or more solar reflector assemblies floating on the supporting body of liquid, each solar reflector assembly including: a primary inflatable elongated tube having an upper portion at least partially formed of flexible material and a lower ballast portion at least partially formed of flexible material, and an axis of rotation oriented generally parallel to a surface of the supporting body of liquid; and a reflective sheet coupled to an exterior wall of the upper portion of the primary tube to reflect solar radiation; and
- a solar collector spaced apart from the primary tube and positioned to receive reflected solar radiation from the reflective sheet;
- wherein the lower ballast portion of the primary tube contains liquid facilitating ballast, the liquid having a top surface generally parallel to the surface of the supporting body of liquid.
17. The system of claim 16 further comprising at least one support component disposed on the exterior wall of the primary tube to support the reflective sheet.
18. The system of claim 17 wherein pressure from air inside the primary tube compresses the support component such that the reflective sheet maintains a substantially rigid configuration.
19. The system of claim 16 wherein the at least one support component is a secondary inflatable tube.
20. The system of claim 16 wherein the primary tube further comprises a culture medium for photosynthetic biomass.
Type: Application
Filed: Oct 10, 2012
Publication Date: Feb 7, 2013
Applicant: Combined Power LLC (Santee, CA)
Inventor: Combined Power LLC (Santee, CA)
Application Number: 13/648,893
International Classification: F24J 2/36 (20060101);