Linear fresnel solar arrays and components therefor
Described herein are solar energy collector systems, components for solar energy collector systems, and methods for installing solar energy collector systems. The components for solar energy collector systems include but are not limited to solar radiation absorbers, receivers, drives, drive systems, reflectors, and various support structures. The solar energy collection systems, solar radiation absorbers, receivers, drives, drive systems, reflectors, support structures, and/or methods may be used, for example, in LFR solar arrays.
Latest Ausra, Inc. Patents:
This application claims the benefit of priority to U.S. patent application Ser. No. 11/895,869, filed Aug. 27, 2007, entitled “Linear Fresnel Solar Arrays,” petition granted to convert to a provisional patent application on Jan. 23, 2008 having U.S. patent application Ser. No. ______ (not yet assigned), which is incorporated by reference herein in its entirety. This application is related to U.S. patent application Ser. No. ______, entitled “Linear Fresnel Solar Arrays and Receivers Therefor” (Attorney Docket No. 62715-20015.00), and U.S. patent application Ser. No. ______, entitled “Linear Fresnel Solar Arrays and Drives Therefor” (Attorney Docket No. 62715-20016.00), each of which is filed concurrently herewith, and each of which is incorporated by reference herein in its entirety.
FIELDThis application relates to solar energy collector systems, and in particular to linear Fresnel reflector solar arrays. Described herein are reflectors, solar radiation absorbers, receivers, drives, support structures, stabilization elements, and related methods, that may be used in conjunction with solar energy collector systems.
BACKGROUNDSolar energy collector systems of the type referred to as Linear Fresnel Reflector (LFR) systems are relatively well known. LFR arrays include a field of linear reflectors that are arrayed in parallel side-by-side rows. The reflectors may be driven to track the sun's motion. In these systems, the reflectors are oriented to reflect incident solar radiation to an elevated distant receiver that is capable of absorbing the reflected solar radiation. The receiver typically extends parallel to the rows of reflectors to receive the reflected radiation for energy exchange. The receiver typically can be, but need not be, positioned between two adjacent fields of reflectors. For example, in some systems, n spaced-apart receivers may be illuminated by reflected radiation from (n+1) or, alternatively, (n−1) reflector fields. In some variations, a single receiver may be illuminated by reflected radiation from two adjacent reflector fields.
To track the sun's movements, the individual reflectors may be mounted to supports that are capable of tilting or pivoting. Examples of suitable supports are described in International Patent Publication Number WO05/003647, filed Jul. 1, 2004, and International Patent Publication Number WO05/0078360, filed Feb. 17, 2005, each of which is incorporated herein by reference in its entirety.
In most LFR systems, the receivers and rows of reflectors are positioned to extend linearly in a north-south direction, with the reflectors symmetrically disposed around the receivers. In these systems, the reflectors may be pivotally mounted and driven through an angle approaching 90° to track approximate east-west motion of the sun during successive diurnal periods. Some systems have been proposed in which the rows of reflectors are positioned to extend linearly in an east-west direction. See, e.g., Di Canio et al., Final Report 1977-79 DOE/ET/20426-1, and International Patent Application Serial No. PCT/AU2007/001232, entitled “Energy Collection System Having East-West Extending Linear Reflectors,” filed Aug. 27, 2007, each of which is incorporated herein by reference in its entirety.
Solar collector systems are generally expansive in area, and are located in remote environments. In addition, solar collector systems must endure for many years in a harsh outdoor environment with relatively low operation, maintenance and repair requirements. Improved systems with reduced requirements for personnel, time, and/or equipment for operation, maintenance, and/or repair are desired. Further, it is desired that solar collector systems be facile to transport to and assemble in remote locations. Therefore, a need exists for improved solar collection systems and improved components for solar collector systems. Such components may include reflectors, receivers, drives, drive systems, and/or support structures. The improved components may lead to improved collection efficiency and improved overall performance for solar collector systems, e.g., LFR arrays. The improved components may also result in reduced operational, maintenance and/or repair requirements, improved longevity in harsh outdoor environments, improved portability, reduced assembly requirements, and reduced manufacturing time and/or costs.
SUMMARYDescribed herein are solar energy collector systems, components for solar energy collector systems, and methods for installing solar energy collector systems. The components for solar energy collector systems include, but are not limited to, solar radiation absorbers, receivers, drives and drive systems, reflectors, and various support structures. The solar energy collection systems, solar radiation absorbers receivers, drives, drive systems, reflectors, support structures, and/or methods may be used, for example, in LFR solar arrays. The components and methods described herein may be used together in any combination in a solar collector system, or they may be used separately in different solar collector systems.
Reflectors for use in a solar energy collector system are described. The reflectors each comprise a reflective surface that is configured to direct incident solar radiation to a solar radiation absorber in an elevated receiver. The reflective surface of the reflectors may be configured to provide a line focus, e.g., the reflectors may be cylindrical mirrors. These reflectors may have a focal length that is greater than a distance between the reflective surface of the reflector and the solar radiation absorber in the receiver. The reflectors may be configured to be driven to at least partially follow diurnal motion of the sun. Some variations of the reflectors may have a focal length that is at least about 1% to about 15% (e.g., about 2%, 5%, or 10%) greater than the distance between its reflective surface and the solar radiation absorber at which the reflector is directed.
Solar energy collector systems including such reflectors are also described here. The solar energy collector systems comprise an elevated receiver comprising a solar radiation absorber. First and second reflector fields are positioned on opposite sides relative to a center of the receiver. Each reflector field comprises reflectors that are arranged into one or more parallel reflector rows that extend generally in a direction that is parallel to a length of the receiver. The reflectors each comprise a reflective surface that is configured to direct incident solar radiation to form a line focus at the solar radiation absorber in the receiver. The reflectors are configured to be driven to at least partially track diurnal motion of the sun. At least one reflector from the first and/or the second reflector field has a focal length that is greater than a distance between its reflective surface and the solar radiation absorber in the receiver, e.g., about 1% to about 15%, or about 2%, about 5%, or about 10% greater than a distance between its reflective surface and the solar radiation absorber. For example, some systems may comprise one or more parallel reflector rows including an outer row, and a reflector positioned in the outer row may have a focal length that is greater than a distance between its reflective surface and the solar radiation absorber.
Other variations of solar energy collector systems are provided. These systems comprise an elevated receiver comprising a solar radiation absorber. First and second reflector fields are positioned on opposite sides relative to a center of the receiver. Each reflector field comprises reflectors arranged into one or more parallel reflector rows that extend generally parallel to the length of the receiver. The reflectors each comprise a reflective surface configured to direct incident solar radiation to the solar radiation absorber in the receiver and to at least partially track diurnal motion of the sun. The reflectors may be arranged so that a focal length of each reflector generally correlates with a distance between that reflector and the receiver.
Sets of asymmetric guy wires for use in stabilizing a vertical support structure in a solar energy collector system are provided. These sets of asymmetric guy wires comprise first and second guy wires. Each of the first and second guy wires has a distal end and a proximal end. The distal end of the first guy wire is configured to be coupled to a distal end of a ground-anchored vertical support structure of a solar energy collector system at a first coupling point. The proximal end of the first guy wire is configured to be anchored to the ground and/or to an anchoring structure at a first anchoring point. The first guy wire has a first resonance frequency between the first coupling and anchoring points when it is coupled to the vertical support structure at the first coupling point and anchored at the first anchoring point. The distal end of the second guy wire is configured to be coupled to the distal end of the vertical support structure at a second coupling point. The proximal end of the second guy wire is configured to be anchored to the ground and/or to an anchoring structure at a second anchoring point. The second guy wire has a second resonance frequency between the second coupling and anchor points when it is coupled to the vertical support structure at the second coupling point and anchored at the second anchoring point. In the sets of guy wires, the first and second resonance frequencies are different.
The guy wires in the sets of asymmetric guy wires may be varied in any suitable manner so that their resonance frequencies are different. For example, in some variations, a length of the first guy wire between the first coupling and anchoring points may be different than a length of the second guy wire between the second coupling and anchoring points to result in first and second resonance frequencies being different. In certain variations, a width of the first guy wire between the first coupling and anchoring points may be different than a width of the second guy wire between the second coupling and anchoring points.
Some variations of the sets of asymmetric guy wires may include more than two guy wires, e.g., three or more guy wires. In such sets, a distal end of a third guy wire is configured to be coupled to a distal end of a ground anchored vertical support structure at a third coupling point. A proximal end of the third guy wire is configured to be anchored to the ground and/or an anchoring structure at a third anchoring point. The third guy wire has a third resonance frequency between the third coupling and anchoring points when coupled to the vertical support structure at the third coupling point and anchored at the third anchoring point. The third resonance frequency is different from at least one of the first and second resonance frequencies.
Solar energy collector systems comprising asymmetric guy wires are provided. These systems comprise an elevated receiver extending in a longitudinal direction and a vertical support structure configured to support the elevated receiver. The systems also include first and second guy wires. The first guy wire is coupled to the vertical support structure at a first coupling point and extends laterally from the vertical support structure to a first anchoring point. The first guy wire has a first resonance frequency between the first coupling point and the first anchoring point. The first anchoring point may be on the ground, or on an anchoring structure. The second guy wire is coupled to the vertical support structure at a second coupling point and extends laterally from the vertical support structure to a second anchoring point. The second anchoring point can be on the ground, or on an anchoring structure. The second guy wire has a second resonance frequency between the second coupling point and the second anchoring point. In these systems, the first resonance frequency is different from the second resonance frequency. For example, the first and second resonance frequencies may differ by at least about 20%, at least about 30%, at least about 40%, or at least about 50%.
Solar energy collector systems including longitudinal guy wires are also described. These systems include an elevated receiver comprising a solar radiation absorber. A plurality of vertical support structures are distributed along a length of the elevated receiver and are configured to support the elevated receiver. The systems each include an arrangement of longitudinal guy wires. In the arrangement of longitudinal guy wires, each longitudinal guy wire extends between two adjacent vertical support structures. The arrangement of longitudinal guy wires is configured to stabilize the solar energy collector system and to accommodate longitudinal thermal expansions of one or more components of the elevated receiver.
These systems may include any suitable arrangement of longitudinal guy wires to provide system stabilization while accommodating thermal expansion in the receiver. For example, in some variations of the systems, the arrangement of longitudinal guy wires may comprise a density of longitudinal guy wires that decreases as a distance from a longitudinal center of the elevated receiver increases. In certain variations, the arrangement of longitudinal guy wires may comprise a first set of generally parallel single longitudinal guy wires. Each single longitudinal guy wire in the first set extends generally in a first diagonal direction between two adjacent ones of the plurality of vertical support structures. Variations of the arrangements of guy wires in the systems may also include a second set of generally parallel longitudinal guy wires. Each single longitudinal guy wire in the second set extends generally in a second diagonal direction between adjacent vertical support structures. In these variations, the first and second sets of longitudinal guy wires may be positioned on opposite sides relative to a longitudinal center of the receiver.
Methods for installing linear Fresnel solar reflector systems are provided. These methods include arranging a plurality of reflectors into rows and providing a receiver body. The receiver body comprises a receiver channel that comprises first and second sidewalls and an aperture each extending along a length of the receiver channel. A plurality of solar radiation absorber tubes is arranged lengthwise into the receiver channel. A window is inserted into the receiver channel in a direction transverse to the length of the receiver channel. The window is secured over the aperture so that the window forms a junction with each of the first and second sidewalls of the receiver channel to form a cavity that houses the solar radiation tubes. The receiver body is oriented so that the length of the receiver channel is generally parallel to the reflector rows. The methods include elevating the receiver body comprising the receiver channel, the solar radiation absorber tubes, and the window to an installed vertical receiver position that is above the plurality of reflectors. The plurality of reflectors are aligned so that each reflector directs incident solar radiation through the window to be at least partially incident on one or more of the solar absorber tubes when the receiver body is in the installed vertical receiver position. In some variations of the methods, the window may be secured to the receiver channel with fasteners before elevating the receiver body to the installed vertical receiver position.
In certain variations of the methods, elevating the receiver body to the installed vertical receiver position may comprise anchoring a proximal end of a jointed vertical support structure to the ground, angling a distal end of the vertical support structure toward the ground, and securing the receiver body to the distal end of the jointed vertical support structure. Lateral force may be applied to the distal end of the jointed vertical support structure to elevate the receiver body. One or more joints of the jointed vertical support structure may be locked when the receiver body is in the install vertical receiver position. For example, in some variations of the methods, the lateral force may be applied to the distal end of the jointed vertical support structure with a tether. In these methods, the tether may be threaded through one or more pulleys to control the application of lateral force to the distal end of the jointed vertical support structure. In other variations of the methods, elevating the receiver body to the installed vertical receiver position may comprise anchoring at least one post of a vertical support structure to the ground, elevating the receiver body using a hoist (i.e., lifting structure) coupled to the vertical support structure, and coupling the elevated receiver to the vertical support structure.
Vertical support structures for use in solar energy collector systems are provided. Certain variations of vertical support structures each include a proximal end configured to be anchored to the ground, and a distal end configured to be coupled to an elevated receiver in a solar energy collector system. The support structures include a first joint that is configured to allow the distal end of the support structure to be angled toward the ground for coupling the receiver thereto at or near ground level while the proximal end of the support structure is anchored to the ground. The first joint is also configured to allow the distal end of the support structure to be elevated with the application of lateral force to the distal end of the support structure so that a receiver coupled thereto can be elevated to a vertical installed receiver position. In some variations of the vertical support structures, the first joint may be configured to be locked in a locked configuration to hold an elevated receiver in the vertical installed receiver position.
Some vertical support structures may include a second joint that is positioned distally relative to the first joint. In these variations of vertical support structures, the second joint can be flexed independently from the first joint. The second joint is configured to allow the distal end of the vertical support structure to be angled more toward the ground than the first joint while the proximal end of the support structure is angled to the ground. The second joint is also configured to allow the distal end of the support structure to be elevated with the application of lateral force to the distal end of the support structure, so that a receiver coupled thereto can be elevated to a vertical installed receiver position. In some variations of these support structures, the second joint may be configured to be locked into a locked configuration to hold an elevated receiver in the vertical installed receiver position.
Some vertical support structures may further comprise a tether that is coupled to the distal end of the support structure. In these variations, the tether may be configured to apply lateral tension to the distal end of the support structure to elevate a receiver coupled thereto. Certain variations of these vertical support structures including a tether further comprise one or more pulleys. In these variations, the tether is configured to be threaded through the one or more pulleys to guide the position of the tether as lateral tension is applied to the distal end of the vertical support structure.
Still other variations of vertical support structures for use in solar energy collector systems are described here. These structures comprise at least one post configured to be anchored to the ground, and a hoist (i.e., a lifting structure) coupled to the vertical support structure. The hoist is configured to lift a receiver. The vertical support structure comprises at least one mounting member configured to support the receiver in an elevated installed position. In some instances, the mounting member may comprise at least one shelf. Some variations of these vertical support structures may comprise two posts that are each configured to be coupled to the ground. The posts may be angled toward each other and interconnected at or near a peak of the vertical support structure. In some embodiments of the vertical support structures, the hoist may be mounted to an auxiliary portion of the vertical support structure. The auxiliary portion may be configured to be removed after the receiver is installed.
Methods for making a carrier frame for supporting reflector elements in a linear Fresnel solar reflector system are described here. These methods comprise providing first and second platforms, where each platform comprises a first end and a second opposite end. A first reflector support is provided that comprises one or more attachment tabs affixed to the first reflector support. In these methods, the first reflector support is fixed to the second end of the first platform. The first reflector support is also temporarily or removably coupled to the first end of the second platform with the one or more attachment tabs, so that the first and second platforms each extend from opposites sides of the first reflector support. The methods include aligning the second platform with the first platform with the one or more attachment tabs. In some variations, for example, the second platform may be aligned with the first platform to within about 5 mm. Some variations of the methods include fixing the first end of the second platform to the first reflector support after aligning the first platform with the second platform.
Some variations of these methods further comprise providing second and third reflector supports. In these variations, the second reflector support is coupled to the first end of the first platform so that the first platform is supported between the first and second reflector supports, and the third reflector support is coupled to the second end of the second platform so that the second platform is supported between the first and third reflector supports.
Carrier frames for supporting reflector elements in a linear Fresnel solar reflector system are provided here. The carrier frames each comprise first and second platforms, each platform comprising first and second ends. The carrier frames comprise a first reflector support and at least one attachment tab affixed to the first reflector support. The second end of the first platform is fixed to the first reflector support. The first end of the second platform is removably attached to the first reflector support with the at least one attachment tab, so that the first and second platforms extend from opposite sides of the first reflector support. The at least one attachment tab is configured to allow alignment of the second platform relative to the first platform and to allow securing of the second platform to the second side of the first reflector support in an aligned position. For example, the attachment tab may be configured to allow rotation and/or translation of the second platform to align the second platform with the first platform. In some carrier frames, the attachment tab may comprise a threaded hole configured to accept a threaded bolt coupled to the second platform. Some carrier frames further comprise second and third reflector supports, wherein the second reflector support is coupled to the first end of the first platform so that the first platform is supported between the first and second reflector supports, and the third reflector support is coupled to the second end of the second platform so that the second platform is supported between the first and third reflector supports.
Methods for installing an elevated receiver into a solar energy collector system are also provided here. These methods comprise anchoring a vertical support structure comprising a hoist to the ground, and lifting a receiver with the hoist. After the receiver is lifted, the receiver is coupled to the vertical support structure to install the receiver in the solar energy collector system. Some of these methods may comprise anchoring a row of vertical support structures to the ground, where at least one of the vertical support structures comprises a hoist. More than one of the vertical support structures in the row may comprise a hoist, e.g., end ones of the row of vertical support structures. In these methods, an elongated receiver is positioned along the row of vertical support structures on or near ground level and lifted with the hoist. After the receiver has been lifted, the receiver is coupled to the vertical support structures to install the receiver into the solar energy collector system. In some variations of the methods, one or more hoists may be removed from vertical support structures after the receiver has been installed.
The following detailed description should be read with reference to the drawings, in which identical reference numbers refer to like elements throughout the different figures. The drawings, which are not necessarily to scale, depict selective embodiments and are not intended to limit the scope of the invention. The detailed description illustrates by way of example, not by way of limitation, the principles of the invention. This description will enable one skilled in the art to make and use the invention, and describes several embodiments, examples, adaptations, variations, alternatives and uses of the invention, including what is presently believed to be the best mode of carrying out the invention.
The terms “solar energy collector system,” “solar collector system,” and “solar array” are used interchangeably throughout this specification and in the appended claims. In addition, unless indicated otherwise, “array” refers to a solar array, and “absorber” refers to a solar radiation absorber. The singular forms “a,” “an,” and “the” include plural referents unless the context clearly indicates otherwise. Also, the term “parallel” is intended to mean “substantially parallel” and to encompass minor deviations from parallel geometries rather than to require that parallel rows of reflectors, for example, or any other parallel arrangements described herein be exactly parallel. The phrase “generally in a north-south direction” or as used herein is meant to indicate a direction orthogonal to the earth's axis of rotation within a tolerance of about +/−45 degrees. For example, in referring to a row of reflectors extending generally in a north-south direction, it is meant that the reflector row lies parallel to the earth's axis of rotation within a tolerance of about +/−45 degrees.
Disclosed herein are examples and variations of solar energy collector systems, components for solar energy collector systems, and related methods. The solar energy collector systems may be LFR solar arrays. The components may include reflectors for directing incident solar radiation to a receiver, receivers for receiving and at least partially absorbing solar radiation, solar radiation absorbers, drives and drive systems for positioning the reflectors, support structures for elevated receivers, support structures or carrier frames for reflector elements, and additional stabilizing elements, such as guy wires, for stabilizing or securing any part of a solar array. The components described here may be used in any combination in a solar energy collector system. Further, any suitable receiver, solar radiation absorber, reflector, drive, drive system, support structure, stabilizing element, or method disclosed herein, known to a person of ordinary skill in the art, or later developed, may be used in the solar collector systems described herein. Receivers, solar radiation absorbers, reflectors, drives, drive systems, associated support structures and stabilizing elements, and methods disclosed herein may be used in other solar collector systems (e.g., LFR solar arrays) known to one of ordinary skill in the art or later developed.
The following is a general description of solar energy collector systems that may be used in conjunction with any one of, or any combination, of the components for solar collector systems that are described below. Additional examples of solar energy collector systems are included throughout this detailed description in connection with specific components and methods disclosed herein, e.g., reflectors, receivers, absorbers, drives, drive systems, support structures, stabilizing elements, and related methods.
Referring to
Referring now to
For systems having multiple reflector fields, the reflector fields may be symmetric or asymmetric with respect to a receiver. The composition and/or arrangement of the reflector fields may, for example, be determined to increase ground area usage and/or system collection efficiency. Referring again to
For a given reflector field, adjacent reflector rows may be spaced apart by a constant row spacing, or by variable row spacings. For example, reflectors in a first reflector row that are less tilted relative to reflectors in an adjacent second reflector row may be packed closer together with the reflectors in the adjacent second row, without causing shading. Referring again to
In certain variations of arrays, the spacing between adjacent reflector rows may vary generally as the distance between the reflectors rows and the receiver. That is, reflector rows closer to the receiver may be spaced closer together than reflector rows further from the receiver. For example, as illustrated in
The use of variable row spacings may allow closer packing of reflector rows, resulting in improved use of ground area and/or reduction of shading of reflectors caused by adjacent reflectors. In some systems, a reflector area to ground area ratio may be greater than about 70%, or greater than about 75%, or greater than about 80%. Combinations of constant spacings and variable spacings between reflector rows may be used. For example, a first group of reflector rows, e.g., those closest to the receiver, may be spaced apart by a first constant relatively narrow spacing. A second group of reflector rows, e.g., those farthest from the receiver, may be spaced apart by a second constant relatively wide spacing. In addition, different spacing schemes may be used between different reflector fields in a single system. For example, one reflector field may have constant reflector row spacings and one reflector field may have variable reflector row spacings. For north-south oriented arrays including reflector rows that are about 2.3 meters wide directing solar radiation to an absorber of about 0.6 meter wide positioned about 15 meters above the reflectors, center-center inter-row reflector separations may range from about 2.6 meters to almost 3 meters (e.g., about 2.9 meters).
It should be noted that the diurnal sun moves through an angle less than about 90° in the north-south direction, as compared with an angle approaching about 180° in the east-west direction. Therefore, for east-west oriented arrays, each reflector in a reflector field need only pivotally move less than about 45° to follow the sun during each diurnal period. As a result, the angles of incidence for reflectors in a polar reflector field are generally less than those for reflectors in an equatorial reflector field. Hence, a reflector in a polar reflector field may have greater effective collection area and produce improved focus at the receiver than a corresponding reflector in the equatorial reflector field positioned the same distance from the receiver. Because of the improved efficiency of polar reflectors, the overall collection efficiency of a solar array may be improved by increasing the relative reflector area in the polar reflector field as compared to the equatorial reflector field, e.g., by increasing the number of reflectors in the polar field.
Solar energy collector systems may comprise multiple elevated receivers, and multiple reflector fields configured to direct incident light to the elevated receivers. Referring now to
A drive system used in the arrays may comprise any suitable reflector supports that are configured to support and rotate one or more reflector elements. In general, the reflector supports comprise a frame portion configured to support one or more reflector elements, a base, and a linkage rotationally coupling the frame portion to the base so that the frame portion may be rotated through the linkage to position the one or more reflector elements. The reflector supports may be selected to reduce the amount of shading from the support on any reflector element, e.g., one or more reflector elements supported by that reflector support and/or one or more reflector elements supported by adjacent or nearby reflector supports. For example, a reflector support in a drive system may be configured such that a frame portion of the reflector support is substantially confined to one side of a planar region generally defined by a reflective surface of one or more reflector elements supported by the frame, e.g., so that the frame is substantially beneath that reflective surface during operation. A reflector support may also be configured to have strength and/or stability, e.g., torsional strength and/or stability, such that one or more reflector elements supported by that reflector support does not substantially twist or distort when that reflector support is rotated.
As described above, a reflector support in a drive system may be configured to be a master reflector support or a slave reflector support, or to be convertible between a master reflector support and a slave reflector support. A master reflector support may be coupled to a drive (e.g., a drive comprising a motor). A slave reflector support may not be directly coupled to a drive, and instead may be coupled to a master reflector support (or another slave support that is coupled to a master support) so that rotation of the master reflector support drives coordinated rotation in the slave reflector support. In that manner, a single drive may be used to rotate a reflector row or reflector row segment. A master reflector and drive may be configured to drive any suitable number of slave reflector supports, e.g., one, two, three, four, five, six, seven, eight, nine, ten, or eleven, or even more.
Some variations of reflector supports that may be used in drive systems for solar energy collector arrays, e.g., linear Fresnel reflector arrays, are illustrated in
Other variations of reflector supports may be used in the drive systems and arrays described herein. Referring now to
Still other variations of reflector supports may be used. Referring to
Any combination of reflector supports and reflector support types may be used within an array or within a reflector row in an array. The combination of reflector supports may be selected to provide increased torsional stability along a row, reduced shading, ease of installation, ease of manufacturing, and/or cost. In some variations of arrays, such as array 201 illustrated in
As indicated above, some arrays may comprise more than one receiver. Array 201 in
A LFR array may occupy a ground area of about 5×103 m2 to about 25×106 m2. For example, an array may comprise a single receiver and two fields of reflectors arranged on opposite sides of the receiver to occupy a ground area of about 8.5×103 m2. Other arrays may comprise multiple receivers and multiple reflector fields to occupy larger ground areas, e.g., about 5×106 m2 to about 25×106 m2. For example, the arrays illustrated in
The reflectors used in the solar energy collector systems may be any suitable reflectors described here, known to one of ordinary skill in the art, or later developed. Non-limiting examples of suitable reflectors are disclosed in International Patent Applications Nos. PCT/AU2004/000883 and PCT/AU2004/000884, each of which is hereby incorporated by reference herein in its entirety.
As illustrated in
Referring now to
As the distance between a reflector and its corresponding receiver increases, the required focal length for the reflector may also increase. Accordingly, the size of the focused image at the receiver may also increase. If the focused image is larger than the receiver, or leaks past the receiver, then the collection efficiency of the receiver may be decreased. Reflectors that are positioned the farthest from the receiver are closest to the periphery of the array. Hence, the angle of incidence on a surface of the receiver increases for peripherally-positioned reflectors, which may lead to increased losses at the receiver, e.g., reflective losses and/or losses due to poor focusing of astigmatic reflections as discussed above.
Referring now to
In some arrays, peripheral reflectors positioned relatively far from a receiver may have focal lengths longer than their distance from the receiver. Some variations of arrays may comprise a series of parallel reflector rows each directing incident light to an elevated receiver. The focal lengths of the reflectors in the respective reflector rows may follow a progression so that those reflectors farthest from a transverse center of the receiver are the longest. Such progressions may include monotonic increases in reflector focal length as a distance from the transverse receiver center increases, or any general trend or general correlation between increasing reflector focal length with increasing receiver-reflector distances. In some arrays, only the outermost reflector rows may comprise reflectors having focal lengths longer than their respective reflective surface-solar absorber distances. For example, for arrays having two reflector fields directed to a single absorber, only two or four of the most peripheral rows may have focal lengths longer than their respective reflective surface-solar absorber distances. Solar energy collector systems utilizing one or more reflectors having focal lengths longer than their distance to the receiver may have overall collection efficiencies, such as annualized light collection efficiencies, that are increased by about 1%, about 2%, about 3%, about 4%, about 5%, about 6%, or even more, e.g., about 10%.
Reflectors may have any suitable dimensions. Of course, reflectors may be unitary n nature, and comprise a single reflector element, or reflectors may comprise multiple reflector elements. Dimensions of reflectors and/or reflector elements may be selected based any combination of the following considerations: system collection efficiency, manufacturing requirements, manufacturing costs, availability of materials, cost of materials, ease of handling and/or transportation, field maintenance requirements, lifetime, and/or ease of installation. In some variations, reflectors may have lengths of about 10 meters to about 20 meters, and widths of about 1 meter to about 3 meters. The reflectors may have lengths of about 10 to about 20 meters, e.g., about 12 meters, about 14 meters, about 16 meters, or about 18 meters, and widths of about 1 meter to about 3 meters, e.g., about 1.3, about 1.4 meters, about 1.5 meters, about 1.6 meters, about 1.7 meters, about 1.8 meters, about 1.9 meters, about 2.0 meters, about 2.1 meters, about 2.2 meters, about 2.3 meters, about 2.4 meters, about 2.5 meters, about 2.6 meters, about 2.7 meters, about 2.8 meters, or about 2.9 meters. The reflectors may have lengths of about 16 meters and widths of about 2.2 meters. In some cases, focal lengths of reflectors or reflector elements may be indicated in a readily discernible manner, e.g., by color coding, to aid in assembly of solar arrays.
One or more reflector rows in a solar energy collector system may have an overall length of about 200 meters to about 600 meters, e.g., about 200 meters to about 400 meters, or about 400 meters to about 600 meters. In some systems, reflector rows may have the same or similar overall lengths. As illustrated in
The receiver or receivers in solar energy collector systems may be any suitable receiver described herein, known to one of ordinary skill in the art, or later developed. Suitable receivers may include, for example, those disclosed in International Patent Application No. PCT/AU2005/000208, which is hereby incorporated by reference in its entirety. Receivers may be, for example, photovoltaic receivers capable of absorbing incident solar radiation and converting the solar radiation to electricity, or thermal receivers capable of absorbing incident solar radiation to heat a working or heat exchange fluid in the receiver. For example, a heat exchange fluid such as water may be flowed through the receiver. As shown in
As indicated above, some variations of receivers may comprise multiple receiver structures. The receiver structures may be interconnected. Receiver structures may be arranged and/or interconnected in a longitudinal (i.e., lengthwise) and/or a transverse (i.e., widthwise) manner to form receivers. Receivers may have overall lengths, including receiver structures, that are similar to the overall length of the corresponding reflector rows, e.g., about 200 meters to about 600 meters (e.g., about 200 meters to about 400 meters, or about 400 meters to about 600 meters). Receiver structures may have lengths of, for example, about 8 meters to about 20 meters and overall widths of about 0.5 meters to about 3 meters, e.g., about 0.5 meters to about 1 meter, or about 1 meter to about 2 meters, or about 2 meters to about 3 meters. For example, in some variations a receiver structure may have a length of about 12 meters and an overall width of about 1.3 to about 1.4 meters. Suitable receivers may have one or more solar radiation absorbers, where the absorbers are tubes and/or flat plates, or groups of tubes and/or flat plates. One or more absorbers, including a group of tubes and/or flat plates making up an absorber, may have a width of about 0.3 meter to about 1 meter, or any other suitable width.
In solar energy collector systems including multiple receivers, receivers may be spaced apart by about 20 to about 35 meters, or by any suitable inter-receiver spacing. The receivers may be elevated above the reflectors with their absorbers positioned at a height of about 10 meters to about 20 meters above the reflectors, e.g., about 15 meters above the reflectors. In arrays with multiple receivers, the receivers may be positioned all at the same or similar heights above the reflectors, or at different heights above the reflectors.
Elevated receivers may be supported by any suitable method. For example, receivers may be supported by vertical support structures such as stanchions, as illustrated in
Guy wires, if present, may extend generally laterally or longitudinally from a vertical support structure. For example, as discussed in more detail below, one or more ground-anchored guy wires may extend laterally from a vertical support structure. Alternatively, or in addition, one or more longitudinal guy wires may extend between adjacent ones of the vertical support structures. Any combination of lateral and/or longitudinal guy wires may be used to stabilize vertical support structures supporting a receiver. For example, at least some vertical support structures may not be stabilized by any lateral guy wires. In other variations, only alternate ones of vertical support structures may be stabilized by lateral guy wires. In still other variations, only every third or fourth or greater interval vertical support structure may be stabilized by lateral guy wires.
When a set of guy wires comprising two or more guy wires is used to stabilize a vertical support structure in a system, one guy wire in the set may be asymmetric relative to another guy wire in the set by having a different spring constant or resonance than the other guy wire. Resonances in guy wires may be excited by external environmental effects such as wind and/or seismic activity, as well as internal effects such as motor vibrations or reflector motions. By selecting a set of guy wires that includes guy wires with different natural resonances to stabilize a support structure, the solar energy collector system as a whole may be stabilized. If the resonance frequencies in guy wires do not match, an excited resonance in one wire may not amplify a resonance in another wire. In addition, if the resonance frequencies of guy wires used to stabilize a support structure are different, an excited resonance in one wire may not couple to and excite the same resonances in the system, again leading to improved system stability. Further, one guy wire in a set may be chosen to have a resonance that can couple with and damp a resonance in one or more different guy wires in the set.
Spring constants or resonances of a guy wire may be varied in any suitable manner, e.g., by changing the length, the material, the tension, and/or a diameter of the guy wire. For guy wires comprising more than one strand, a spring constant of the guy wire may be varied by varying the number of strands, the diameter, and/or the material composition of one or more strands. In addition, a pattern of weaving, braiding, and/or intermeshing of strands used to form the guy wire may be changed to adjust a spring constant of the wire.
For the array 501 illustrated in
As indicated above, the natural resonance frequencies of guy wires may be tuned using techniques other than or in addition to changing wire length. For example, as illustrated in
Asymmetric guy wires in a set of guy wires may have resonance frequencies that are different by any suitable amount to improve stability in a solar energy collector system. For example, one guy wire in a set may have a resonance frequency that is about 20%, about 30%, about 40%, about 50%, about 60%, about 70%, or about 80% different than another guy wire in the set. As used herein, when two guy wires are referred to as having different resonance frequencies, it is meant that two guy wires should not have the same fundamental resonance frequencies, and also should not be overtones or harmonics of each other.
Guy wires may be selected and arranged in any suitable manner to support and stabilize a series of vertical support structures in a solar array. For example, as shown in
As shown in
Some vertical support structures, e.g., a vertical support structure at the end of a row of vertical support structures supporting an elongated receiver, may be stabilized by a set of guy wires that includes more than two guy wires, e.g., three or four guy wires. Sets of guy wires comprising three or more guy wires may comprise any combination of symmetric and asymmetric guy wires, as long as at least one of the guy wires in the set has a different resonance frequency than another of the guy wires in the set.
In addition to laterally-extending guy wires, an arrangement of longitudinal guy wires may be included in arrays to stabilize elevated receivers and/or other portions of the arrays. For example, an arrangement of longitudinal guy wires may assist in longitudinal system stabilization for seismic events or other motions that excite longitudinal modes in the system, whereas laterally-extending guy wires may provide stabilization against wind and/or seismic events that may primarily excite transverse modes in the system.
For some receivers such as thermal receivers, the absorption of solar radiation can cause a large increase in temperature for one or more receiver components. These large temperature fluctuations will cycle with the diurnal path of the sun. For elongated receivers, extensive anisotropic thermal expansion and contraction may occur. For example, some elongated thermal receivers comprise a plurality of solar absorber tubes (e.g., metal pipes carrying a heat exchange fluid such as water and steam). As the absorber tubes absorb radiation and increase in temperature, an anisotropic expansion occurs primarily along the length of the tubes. For elongated receivers having lengths of 200 meters or more, thermal expansion and contraction on the order of centimeters or tens of centimeters may occur. Arrangements of support structures and stabilizing elements (e.g., longitudinal guy wires) for elevated receivers that can accommodate repeated thermal expansion and contraction are desired. For example, as illustrated in
Examples of suitable arrangements for longitudinal guy wires that may be used to stabilize elevated receivers are shown in
The density of longitudinal guy wires may be decreased in any suitable manner. For example, as illustrated in
Referring now to
Variations of improved receivers for use in solar energy collector systems are described here.
In general, as shown in
In some variations of receivers, a window may be disposed in the aperture. The window may be substantially transparent to a broad portion of the solar radiation spectrum, e.g., the portion of the solar radiation spectrum that passes through the atmosphere. The window may be positioned over a portion of the aperture, or may substantially cover the aperture. Windows may be planar or curved. For example, windows may be curved with a concave surface facing the solar radiation absorber. As illustrated in
As indicated above, the receiver channel (and the window disposed over the aperture, if present) forms a longitudinal cavity that houses the solar radiation absorber and may increase the collection efficiency of the absorber. The receiver channel may function to retain heat in the cavity and to increase energy conversion efficiency, e.g., by reflecting stray solar radiation back to the absorber, providing a still air environment around the absorber to reduce convective losses, and/or have a construction that reduces or eliminates thermal shorts that conduct heat away from the absorber. For a solar radiation absorber to be positioned substantially within the receiver channel, it is meant that a substantial part of the absorbing portion of the absorber is positioned inside the receiver channel, but that portions of the absorber may extend outside the receiver channel, e.g., pipe extensions, pipe fittings, pipe couplings, header manifolds, and/or valves may be positioned outside the receiver channel.
Some variations of receivers may include one or more window support members that are configured to allow installation of a window in a direction that is transverse to the length of the receiver channel. The one or more window support members may also function to support a window once it has been installed into a receiver. Because of the length of the elongated receivers used in some solar collector systems such as LFR solar arrays, transverse installation of windows may be easier than longitudinal installation. Windows may be easier to handle in a transverse direction, leading to reduced risk of window breakage and reduced space requirements for the installation. In addition, transverse installation of windows into receivers may facilitate assembly of those receivers at or near ground level, rather than after they have been elevated above reflector fields.
Window support members that allow transverse installation of a window into a receiver may be disposed along one or both of the first and second longitudinal sidewalls of the receiver channels in the receivers. Window support members may be continuous, e.g., a continuous slot designed to be slidably engaged with an edge of a window, or a continuous ledge designed to support a window. Alternatively, a window support member may be discontinuous, e.g., a series of periodic structures spaced along the length of the receiver channel. For example, a window support member may comprise a series of slot sections designed to be slidably engaged with an edge of a window, or a series of ledge sections.
Referring now to
Some variations of receivers may include two window support members that allow transverse installation of a window into a receiver and subsequent support of that window in the receiver once it has been installed. Referring again to
As shown in
In some variations, tabs (e.g., spring tabs) may be used to secure windows to receivers. Any suitable tabs may be used, and tabs may be distributed along the length of the receiver channel as necessary to secure the window in the receiver. Referring now to the bottom plan view of the receiver in
Other variations of receivers are illustrated in
Windows may include any suitable number of window sections. For example, a rectangular window having dimensions of approximately 1 meter by approximately 10 meters may comprise 5 window sections, each having dimensions of approximately 1 meter by approximately 2 meters. Although window 1227 is depicted in
Utilizing a window in a receiver that comprises overlapping window sections may present certain advantages over the use of windows comprising non-overlapping window sections. A joint between window sections that comprises an overlapped regions may not require additional sealing of that joint to prevent leakage in or out through that junction. Also, the friction between overlapping window sections may prevent the migration or “walking” of window sections relative to each other, or to the receiver channel. Such migration of window sections may be caused by vibration within a solar energy collector system and/or by thermal expansion and contraction of one or more receiver components. In addition, overlapping window sections may be able to accommodate expansion and contraction due to thermal cycling of the glass and/or other components in the receiver.
Solar energy collector systems including such receivers with a window comprising overlapping window sections are also provided. Receivers such as those illustrated in
Some variations of receivers may include other features that accommodate longitudinal thermal expansion. For example, receiver channels may comprise multiple sections that may slide or longitudinally translate relative to each other. Thus, as illustrated in
One or more receiver channel sections in a receiver may be supported by a frame. For example, as illustrated in
Some variations of receiver channels may comprise one or more expandable elements (not shown) placed between adjacent receiver channel sections. Non-limiting examples of suitable expandable elements include elements with one or more folds that can be at least partially unfolded in the longitudinal direction, such as an accordion-shaped element, a fibrous element, a woven element such as a metal screen or mesh, a spring element, and/or an elastomeric element. Expandable elements, if present between sections of a receiver channel, may be lined with a reflective surface (e.g., a metal coating or a metal foil) to reduce thermal losses and/or to improve the reflection of stray light back to one or more solar absorbers present in the receiver channel.
Some variations of receivers may comprise multiple receiver sections that are coupled together with expansion joints. Referring back to
Additional receiver designs are provided that may reduce the amount of buildup on a receiver window from external environmental contaminants. The reduced buildup on the windows may lead to receivers that have improved collection efficiencies, longer field lifetimes and/or reduced maintenance requirements. Referring now to
A junction may be formed between a window and a receiver channel. The junction may be present along one or both longitudinal sides of the receiver channel. For the example shown in
Some variations of receivers may comprise a thermally insulating material 1447 disposed in all or a portion of volume 1446. In these receivers, air traveling through volume 1446 to reach cavity 1445 may contain air contaminants such as dirt and moisture. These contaminants may be at least partially filtered out by the insulating material 1447 before that air contacts the inner surface 1451 of window 1427. Any suitable insulating material may be disposed in the volume between a roof of the receiver and the receiver channel that permits airflow through the insulating material. For example, fiberglass, glass wool, and/or an open cell foam may be used. Optionally, the insulating material may be at least partially clad with a reflective metal layer to inhibit heat conduction and heat radiation out of the cavity 1445. If used, an air-permeable reflective metal layer may be selected, e.g., a perforated metal foil or a metal mesh.
The passage of air into the cavity housing the absorber through a junction between a receiver channel and a window may be inhibited relative to the passage of air into the cavity through the volume above the receiver channel using any suitable scheme. For example, in some variations, a sealing member may be positioned in a junction between a window and a receiver channel.
Alternatively, or in addition to using a sealing member in a junction between a window and a receiver channel, a positive pressure of filtered or otherwise purified air may be supplied into the cavity to inhibit the ingress of external air into the cavity. For example, dry nitrogen, or purified air that has been passed over a desiccant and/or through a filter (e.g., a particle filter) may be flowed into the cavity to inhibit ingress of external air into the cavity. As illustrated in
In some variations of arrays, filtered air may be directed into a receiver through a supporting structure. Referring now to
In other variations of receivers, an air path through the insulating material may be facilitated to cause air flow to preferentially enter the cavity through the insulating material rather than through the junction between the window and the receiver channel. For example, a rate of air flow through the insulating material may be greater than a rate of air flow through the junction between the window and the receiver channel. The rate of air flow through the insulating material may be increased in any suitable manner. For example, as illustrated in
Non-limiting variations of various vent configurations are illustrated in
Additional variations of receivers are provided here. These receivers comprise a roof extending along a length of the receiver channel. Some roofs may have corrugations extending longitudinally along a length of the roof, e.g., roofs formed from corrugated metal sheets. Another variation of a roof may have a transverse cross-section that forms a smooth outer surface with a concave surface facing the channel and a solar radiation absorber housed in the channel. The transverse cross-section of the roof may have profile that generally follows a parabola, an arc of a circle or an ellipse, or may have a peaked profile, or any other smooth surface that is generally without horizontal surfaces or crevices or other features that may trap or retain environmental debris. A roof having a smooth outer surface may also have a reduced wind profile. The structure of the roof, including its cross-sectional profile, may be selected to impart increased strength and/or rigidity (e.g., longitudinal stability) to the receiver. For example, a roof having a parabolic profile or a profile following an arc of a circle or an ellipse may impart longitudinal rigidity to an elongated receiver to reduce bending and/or torsion. The roof is configured to shed environmental debris (e.g., dust, dirt, and/or moisture) away from the window. In some variations, the roof may be configured to shed environmental debris below a junction between the window and the receiver channel.
Referring now to
Any suitable material or combination of materials may be used for receiver roofs. For example, a metal sheeting material may be used, such as steel, or a galvanized metal sheet. Curved or peaked metal sheets formed into roofs may provide a roofs with smooth, downward-sloping surfaces capable of shedding environmental debris away from the window, and may also impart longitudinal stability to the receiver, e.g., by resisting longitudinal bending and/or torsion. Other variations may include roofs at least partially formed from plastics, e.g., reinforced lightweight composites that have properties to withstand continuous UV exposure and high temperatures experienced by the receivers. In some variations, the roofs may comprise an additional layer such as a rubber layer that may provide enhanced water, dust, and/or UV resistance.
As described above, the receivers in thermal solar energy collector systems such as LFR solar arrays may comprise a plurality of solar absorber tubes that are configured to absorb incident solar radiation and to transfer energy from the solar radiation to a heat exchange fluid (e.g., water and steam) carried by the tubes. Because the temperature of the solar absorber tubes may vary dramatically over the course of a day with the movement of the sun, the tubes expand, contract and move. In some receivers, movement of tubes relative to each other may be accommodated to maintain inter-tube spacings, and/or to reduce damage or stress in the tubes and/or associated structures. Referring now to
The number and/or dimensions of absorber pipes or tubes in an absorber may be selected for specific system requirements. However, it is generally desired that each absorber tube have a diameter that is small relative to a cross-sectional dimension of the aperture of the receiver channel (e.g., aperture 1609 in receiver channel 1619 in
Individual absorber tubes may or may not be spaced apart by one or more spacers. In some variations, tubes may be spaced together as closely as possible, e.g., touching or with small intervening (not necessarily fixed) gaps of about 1 mm to about 4 mm, e.g., about 2 mm, or about 3 mm. In other variations, spacers may be used to provide or maintain spacings between at least some, but not necessarily all, adjacent ones of the plurality of tubes while accommodating thermal expansion, contraction, and movement. Referring again to
In some variations of receivers, absorber tubes may be coated with a solar absorptive coating. The coating may comprise, for example, a solar spectrally selective surface coating that remains stable under high temperature conditions in ambient air, for example, a black paint that is stable in air under high-temperature conditions. Non-limiting examples of solar spectrally selective coatings are disclosed in U.S. Pat. Nos. 6,632,542 and 6,783,653, each of which is incorporated herein by reference in its entirety.
To increase the collection efficiency of a receiver, the amount of light leaking past or between absorber tubes may be reduced. In addition, relatively uniform irradiation of absorber tubes may be desired, e.g., to reduce the formation of hot spots which may lead to inefficient energy conversion. Referring now to
So that light does not leak past the outer circumferential edges of the first absorber tube 1711′, first reflector 1717 may be oriented so that its outer edge 1716 is aligned with a tangent extending from outer circumferential edge 1714′ of first absorber tube 1711′. Similarly, second reflector 1718 may be oriented so that its outer edge 1722 is aligned with a tangent extending from outer circumferential edge 1714″ of second absorber tube 1711″. Angle α indicates approximately the largest angle of incidence (relative to normal 1790) for a ray directed from first reflector 1717 to first absorber tube 1711′, and angle β indicates approximately the largest angle of incidence for a ray directed from second reflector 1718 to second absorber tube 1711″.
Referring now
Improved receivers may be designed to reduce the number and/or effectiveness of thermal conduction paths (i.e., thermal shorts) between the cavity housing the solar radiation absorber and other structures in the receiver. Reducing thermal shorts may increase solar collection efficiencies of a receiver or of a solar energy collection system comprising such a receiver, e.g., by about 2%, about 3%, about 5%, or even more. Referring now to
Other types of thermal separation members may be used between metal structures in a receiver to reduce heat conduction away from the receiver channel. For example,
Thermal separation members may have any suitable dimensions that can effectively reduce or interrupt thermal contact, e.g., by reducing or eliminating the contact area between two thermally conductive (e.g., metal) surfaces. Any suitable thermal separation members may be used. As discussed above in connection with
As indicated above, for example, in connection with
In some variations of receivers, rollers for supporting heat exchange-fluid tubes may be designed that required a reduced amount of energy to turn. Examples of such rollers are illustrated in
In some variations of rollers such as those illustrated in
Variations of receivers may include one or more sets of coaxial, independently rotating rollers to support a group of absorber tubes. These designs may accommodate differential thermal expansion between absorber tubes to reduce friction between the tubes and the roller. An example of such a receiver is illustrated in
Variations of absorbers for use in receivers of solar arrays are provided here that can accommodate longitudinal thermal expansion of absorber tubes and/or increase the efficiency of energy conversion between incident solar radiation and a heat exchange fluid. Examples of such absorbers are illustrated in
Pipes may be arranged to reduce heat loss from pipes containing relatively hot fluid, and to accommodate the difference in temperature between incoming and outgoing heat exchange fluid. For example, in some instances an input/output header may be divided into an input section and an output section to accommodate the differential thermal expansion between these two classes of pipes. Referring now to the example illustrated in
Solar absorbers may comprise any combination of a variety of features to accommodate tube thermal expansion, and in particular, differential thermal expansion and contraction of the tubes along the length of the receiver. Some solar absorbers may comprise a moveable header (e.g., an input/output header and/or a turnaround header). These headers comprise at least a section or portion that can move to accommodate tube thermal expansion. Alternatively, or in addition, solar absorbers may comprise a header manifold that comprises first and second header sections, where the first header section is configured to move independently of the second header section. For example, in the variation illustrated in
Some absorbers may comprise pipe configurations or tube structures extending beyond the receiver body that can accommodate differential thermal expansion and contraction. Such pipe configurations or tube structures may, for example, comprise one or more bends that may expand, contract, and/or twist to accommodate pipe length changes. One example of such a tube structure is one that comprises two or more bends between an input/out header manifold and the receiver, where at least two of the two or more bends are not in the same plane as each other. For example, two bends may be in planes that are approximately orthogonal to each other. In these variations, the expansion of the pipe may lead to torsional movement via expansion through the two bends that reduces stress on the pipe and/or pipe joints. Referring again to
As stated above, absorbers may comprise one or more turnaround headers located at the opposite end of the receiver from the input/output header. Steam and water flowing from the input/output header to the opposite end of the receiver may enter a turnaround header and exit the turnaround header to flow back toward the input/output header. For example, the variation of the solar radiation absorber 2010 illustrated in
In some variations of absorbers, all pipes are connected to an input/output header via tube structures as illustrated in
Header manifolds and/or tubes may comprise additional features to control the flow between absorber tubes. If the level of a heat exchange fluid in an absorber tube becomes too low, a thermal runaway situation may result causing decreased performance and/or damage to a receiver. For example, if water is being used as a heat exchange fluid, and the level of water in a tube is too low, the steam-water ratio may be increased, which, in turn, may lead to an increased pressure drop in that tube. A localized increased pressure drop in an absorber tube will cause the steam-water ratio in that tube to increase even more, leading to a thermal runaway situation in which that absorber tube may eventually become dry. To avoid a thermal runaway situation and resulting dry absorber tubes, an arrangement of solar absorber tubes making up a solar absorber may be provided in which the pressure drops across all tubes are maintained to be relatively constant. If the pressure drops across all tubes are maintained to be relatively constant, then the water flow down each tube will be approximately the same.
If the pressure drop across each absorber tube is dominated by the pressure drop at a tube orifice (e.g., an end orifice), other smaller pressure drops along a tube (e.g., due to local turbulence and/or local heating) may not cause significant fluctuations in pressure drop in that tube. For example, one or more flow control elements may be inserted in one or more tube orifices to control the pressure drop therein. Some flow control elements may, for example, cause a pressure drop in a tube that is about 40%, about 50%, or about 60% of the total pressure drop across the pipe from its turnaround point to its outlet. Flow control elements may be inserted at any suitable position along the pipes. For example, in some cases, flow control elements may be inserted in a turnaround header, e.g., to control the flow of fluid exiting the turnaround header to return to an input/output header. Referring back to
Flow control elements may have any suitable configuration. For example, as illustrated in
In receivers comprising a plurality of solar radiation absorber tubes for carrying a heat exchange fluid, fluid flow through the tubes may be designed to reduce heat losses from the tubes. Thus, as described in International Patent Application Number PCT/AU2005/000208, which has already been incorporated by reference herein in its entirety, absorber tubes containing relatively high fluid temperatures may be positioned near the interior of an arrangement of parallel tubes making up a solar absorber, and correspondingly, tubes containing the coldest fluid may be positioned toward the periphery of the arrangement of parallel tubes. In some variations of receivers, fluid flow through absorber tubes may be in unidirectional streams. Other fluid flow arrangements may be used.
Alternative fluid flow patterns may be used to meet fluctuating load demands and/or adjust for prevailing ambient conditions. For example, selected ones of absorber tubes in a receiver or receiver structure may be closed. In
Any suitable method or scheme may be used to install an elevated receiver above one or more reflector fields. For example, a series of vertical support structures may be anchored to the ground similar to vertical support structures 218 shown in
In some situations, it may be desirable to reduce or eliminate the number of aerial welds or other aerial assembly steps that must be performed. In those instances, the receiver may be partially or entirely assembled on the ground and then elevated in its assembled (e.g., welded) form. To avoid or minimize crane use, one or more vertical support structures that may eventually be used support the elevated receiver during array operation may also be used to elevate a receiver. Referring now to
In some variations, these vertical support structures may comprise one or mounting members to support a receiver. Mounting members may have any suitable configuration, e.g., shelves, hooks, cross-bars, and the like. For example, vertical support structure 3101 in
Some arrays may comprise variations of vertical support structures that have graded leg thicknesses to reduce shading of reflectors by upper portions of the legs. Referring now to
Although vertical support structures 3101 in
Methods are also described for installing an elevated receiver into a solar array using vertical support structures that may eventually be used to support the elevated receiver during operation of the array. These methods generally include anchoring a vertical support structure to the ground, elevating the receiver to an installed receiver position with the vertical support structure (e.g., with a hoist coupled to the vertical support structure), and then supporting the receiver with the same vertical support structure during operation of the array. For example, a hoist coupled to the vertical support structure may be used to lift a receiver or portion of a receiver (e.g., a receiver body or a receiver structure). Non-limiting examples of vertical support structures that may be used in these methods are provided in
In these methods, an assembled or partially assembled elongated receiver may be positioned along a row of spaced-apart vertical support structures at or near ground level. For example, the receiver may be assembled or partially assembled on a stand along a row of vertical support structures. The receiver may then be elevated by one or more of the vertical support structures to an installed receiver position. For example, at least one of the vertical support structures in the row may comprise a hoist configured to lift the receiver. It should be pointed out that not all of the vertical support structures in the row need be capable of lifting the receiver. For example, in some instances, a vertical support structure that is centrally located within the row may comprise a hoist to elevate an elongated receiver, and then the elevated receiver may be coupled to the other vertical support structures in the row in an installed receiver position. The receiver may continue to operate in an array this installed position. In other variations, two of a row of vertical support structures may each be capable of elevating the receiver, e.g., each may comprise a hoist. Those two vertical support structures may be end ones of the row, for example. In still other variations, more than two of a row of vertical support structures in a row may be capable of elevating a receiver, e.g., by comprising hoists. Although the examples of vertical support structures shown in
Some variations of solar collector energy systems may incorporate jointed vertical support structures. These vertical support structures may be designed to support an elevated receiver above one or more reflector fields, e.g., a first reflector field and a second reflector field. The jointed vertical support structures may allow a receiver or receiver structure, or a portion of thereof, to be coupled to the support structure at or near ground level, and then the joint may operate so that the receiver or portion thereof can be elevated to an installed vertical receiver position.
Referring now to
Lateral tension may be applied to the distal end of a jointed vertical support structure in any suitable manner. For example, a tether may be coupled to the distal end of the vertical support structure, and lateral tension applied to the tether to elevate the distal end. Some vertical support structures include a tether as part of the vertical support structure. One or more pulleys may be used to guide and control the direction and amount of tension applied to the tether. The pulleys may be part of the vertical support structure, e.g., mounted to the side of a vertical support structure. Alternatively, or in addition, one or more pulleys may be used that are separate from the vertical support structure.
In some variations, joints in vertical support structures may be lockable. For example, joint 2243 in
Some variations of jointed vertical support structures may comprise more than one joint. Referring now to
Methods for installing LFR solar arrays using vertical support structures such as those illustrated in FIGS. 22 and 23A-23B are provided. These methods include arranging a plurality of reflectors into reflector rows. A receiver body may be provided that includes an elongated receiver channel that comprises first and second longitudinal sidewalls extending along a length of the receiver channel, and an aperture disposed between the first and second sidewalls. The aperture may extend along the entire length of the receiver channel, or along a portion of the length of the receiver channel. The receiver body may be oriented so that the length of the receiver channel is generally parallel to the reflector rows. The methods include elevating the receiver body above the plurality of reflectors. The plurality of reflectors maybe aligned so that each reflector directs incident solar radiation through the aperture of the receiver body.
In some methods, elevating the receiver may comprise anchoring a proximal end of a jointed vertical support structure to the ground and angling a distal end of the vertical support structure toward the ground. The receiver body may then be secured to the distal end of the jointed vertical support structure at or near ground level. Then lateral force may be applied to the distal end of the jointed vertical support structure to elevate the receiver body to its installed vertical position. Lateral force may be applied using a tether connected to the distal end of the jointed vertical support structure, e.g., as shown FIGS. 22 and 23A-23B. The tether may be threaded through one or more pulleys may be used to guide and/or control the application of lateral tension using the tether. In other methods, elevating the receiver to an installed receiver position may comprise elevating the receiver with a vertical support structure (e.g., with a hoist coupled to the vertical support structure) that may eventually support the receiver during operation of the solar array. Examples of such methods of elevating the receiver were discussed above in connection with
In some variations of the methods, a solar radiation absorber may be installed in the receiver channel of the receiver body before the receiver body is elevated. For example, as shown in
Carrier frames for supporting reflector elements in a solar energy collector system and methods for making such carrier frames are provided. These carrier frames may be used for supporting reflector elements in LFR solar arrays. Referring to
Platforms may comprise a corrugated base layer. Such a construction may facilitate curving the platform surface so that a reflector element conforming thereto will have a desired radius of curvature, e.g., as discussed in connection with
In many instances, it may be desired to reduce the amount of water and other contaminants retained or pooled by carrier frames and the like. For example, if multiple corrugated sections are used to form a carrier layer (e.g., similar to layer 2431 in
The attachment tabs may be configured to permit alignment of the second platform relative to the first platform and to allow securing of the second platform to the first reflector support in an aligned position. For example, as illustrated in
Some carrier frames may comprise second and third reflector supports so that the first platform is coupled to and supported between the first and second reflector supports, and the second platform is coupled to and supported between the first and third reflector supports. Referring again to
Although the reflector supports are shown as having hoop-like frames in
Drives and drive systems for solar energy collector systems are provided. In general, the drives include a motor that is configured to move and position one or more reflector supports (e.g., one or more hoops supporting one or more reflector elements). The drives may position the reflector elements to at least partially track diurnal motion of the sun and to reflect incident solar radiation to an elevated receiver. In addition, the drives may be designed to move the reflector elements to a storage position during limited- or no-sunlight hours, and/or during high wind or other inclement weather situations. In general, the drive systems include a motor and one or more reflector supports (e.g., one or more hoops supporting one or more reflector elements). In the drive systems, the motor and the reflector supports are coupled together to allow the desired movement and positioning of the reflector elements.
Some drive systems for solar energy collector systems comprise a bidirectional motor that is configured to drive a gear and a reflector support that is, in turn, configured to support and rotate one or more reflector elements coupled thereto. The reflector support may be configured to rotate the reflector elements to at least partially track diurnal motion of the sun, and to move the reflector elements to a storage position during darkness and/or inclement weather. A chain may be engaged with the gear. The chain may be configured to wrap around an outer peripheral surface of the reflector support and to continuously engage with an engagement member that is affixed to the outer peripheral surface of the reflector support so that the motor can rotate the reflector support via the chain.
In drive systems that include a motor and chain to drive a reflector support, it may be necessary to adjust the tension in the chain to reduce slack, and hence to reduce backlash and the like to improve the accuracy with which the reflector support may be positioned. Referring now to
Other drive systems for use in solar energy collector systems are described. These drive systems include a motor configured to drive a reflector support that supports and rotates one or more reflective elements. These systems are designed to have reduced lateral movement of the reflector support in the drive system, which may improve accuracy of positioning of the reflective elements, and/or reduce extraneous motions to conserve energy. Referring now to
Still referring to
Drives for use in a solar energy collector system are described here, where the drives may comprise a motor and a positional sensor. The motor may be configured to rotate one or more reflector supports, where each reflector support is configured to support and rotate one or more reflector elements coupled thereto. The reflector elements may be aligned and configured to direct incident solar radiation to an elevated receiver. The drives also may each comprise a positional sensor that is configured to sense a rotational position of the reflector support to within at least about 0.2 degrees, at least about 0.1 degrees, at least about 0.05 degrees, at least about 0.02 degrees, or at least about 0.01 degrees. In some variations, the drives may further comprise a controller. In those instances, the controller may be configured to provide input to the positional sensor and/or to receive output from the positional sensor. A controller, if present, may be interfaced with the positional sensor and with a user in any suitable manner. The sensor and the controller may be each configured to receive analog input and/or output, and/or digital input and/or output. For example, the controller may be hard-wired to the positional sensor through a serial or parallel port. Alternatively, or in addition, the controller may have a wireless interface with the sensor. The controller may be hard-wired or wirelessly interfaced with a user interface (e.g., a user-controlled computer connected to the controller through a serial or parallel port), or the controller may be wirelessly interfaced with a user interface. In some variations, the controller may be remotely programmable so that instructions may be remotely sent and/or received from the controller. Some variations of these drives may comprise a closed-loop control configuration in which the controller is configured to receive input from the positional sensor to determine the rotational position of the reflector support, and to provide output instructions to the motor or to a controller interfaced with the motor to rotate the reflector support and the reflector elements coupled to the reflector support to a desired rotational position.
The positional sensor may be configured to sense a rotational position of the reflector support when the reflector support has stopped moving, or the positional sensor may be configured to sense a rotational position of the reflector support while the reflector support is moving. In the latter case, the time constant of the reading by the sensor may be selected according to the speed at which the reflector support is rotating. For example, the time constant of the positional sensor may be selected to be about 50 ms to about 5 seconds, e.g., about 100 ms to about 500 ms, or about 500 ms to about 1 second. Any suitable positional sensor may be used in the drives and systems described here. Analog and/or digital sensors may be used. In some variations, a sensor comprising at least two elements may be mounted to the reflector support. By analyzing the difference between measurements made by the at least two elements, the sensor may determine an absolute or relative tilt of the reflector support. The at least two elements may be any suitable type of elements, e.g., capacitive elements or accelerometers. Non-limiting examples of suitable absolute and/or relative tilt sensors and/or inclinometers that may be used as sensors are available from U.S. Digital (Vancouver, Wash.), Rieker, Inc. (Aston, Pa.), Kelag Künzli Elektronik AG (Switzerland), VTI Technologies (Finland), National Instruments (Austin, Tex.), and Analog Devices (Norwood, Mass.). If a sensor capable of detecting absolute tilt is used as a positional sensor, it may be positioned to within about 10 cm of a center of the reflector support to minimize gravitational effects on the sensor and associated errors. Other types of positional sensors may be used, e.g., inductive sensors or optical sensors.
Positional sensors, if present, may be located on any suitable portion of a reflector support or carrier. For example, a positional sensor may be located on reflector support frame or on a reflector support base. In some variations, a positional sensor may be located on a hoop-like portion of a reflector support frame, on a cross member or spoke of a reflector support frame, or near a center of rotation of a reflector support or reflector element. Referring back to the example illustrated in
Some drives may include one or more limit sensors in addition to the positional sensor. In these drives, the limit sensor may be capable of detecting when the reflector support has rotated to a corresponding limit position. The limit sensors may be able to detect a position of a reflector support to within about 1 degree, about 0.5 degree, about 0.4 degree, about 0.3 degree, about 0.2 degree, about 0.1 degree, about 0.05 degree, or about 0.02 degree. Limit sensors may, for example, be positioned at about 270° relative to each other, e.g., as illustrated in
In some variations of drives, the motor may be configured to be coupled to a variable frequency drive to control the rotational position resolution. In these drives, an AC motor (e.g., a three phase, 480V AC induction motor) is configured to drive a reflector support that is configured to support and rotate one or more reflector elements coupled thereto. The motor may be interfaced with a variable frequency drive to step down the frequency of the AC input, thereby allowing the motor to move less with one AC cycle. For example, nominal 50 Hz or 60 Hz AC power may be stepped down to about 1 Hz to about 6 Hz, or to about 1 Hz to about 5 Hz, to improve the ability of the motor to make smaller incremental rotational movements of the reflector support. Any suitable variable frequency drive may be used. The variable frequency drives may comprise an analog or digital controller. For example, some variable frequency drives may be programmable (e.g., remotely programmable) through a serial or parallel port. Inputs and/or outputs from the variable frequency drives may be hard-wired and/or wireless.
In some variations of these drives, the motor may be configured to be switched between direct AC drive operation and operation through the variable frequency drive. Bypassing the variable frequency drive (VFD) may allow rapid rotation of the reflector elements, e.g., to a storage configuration for limited- or no-sunlight hours, and/or in preparation for inclement weather such as high winds. In some cases, the AC motors operating through a VFD may be driven at a harmonic of the nominal AC power frequency (e.g., 50 Hz or 60 Hz). For example, motors may be driven at 100 Hz, 120 Hz, 150 Hz, or 180 Hz for even faster and/or more efficient rotation of the reflector elements.
Some variations of drives may be capable of driving reflector supports at more than one rotational speed setting. For example, some drives may have a first slow rotational speed setting for relatively slow movement of the reflector support with a relatively high degree of rotational position accuracy and a second rotational speed setting corresponding to motor speeds that allow relatively faster rotation of the reflector support. Some variations may comprise a third rotational speed setting corresponding to very rapid rotation of a reflector support, e.g., the most rapid rotation of the reflector support desired. Different rotational speed settings may be achieved by supplying AC power having different frequency ranges to the motors in the drives. For example, the first rotational speed setting may be achieved by supplying AC power to a motor through a variable frequency drive operating at about 1 Hz to about 6 Hz, or about 1 Hz to about 5 Hz, e.g., at about 2 Hz or about 3 Hz. The second rotational speed setting may be achieved by operating a motor in direct drive at the nominal AC power frequency in the region where the drive is to be operated, e.g., about 50 Hz or about 60 Hz, e.g. The variable frequency drive connected to the motor may be bypassed to operate the motor in direct drive for the second rotational speed setting. The third rotational speed setting, if present, may be achieved by supplying AC power at a harmonic of the nominal AC power through the variable frequency drive to a motor, e.g., at about 100 Hz, or about 120 Hz.
Drive systems are provided in which one or more VFDs may be configured to be connected to a set of motors. In these drive systems, each motor in the set may be configured to drive one or more reflector supports, and each reflector support may be configured to support and rotate one or more reflector elements coupled thereto. For example, as illustrated in
As indicated above, some variations drive systems may comprise one or more switches configured to bypass the variable frequency drive so that the at least one motor of the set of motors may operate in direct drive. Referring again to
Drive systems may be configured such that the reflector rows in a solar array may be rotated in a serial manner (i.e., one reflector row at a time), or so that more than one reflector row may be rotated at the same time. For example, reflector rows may be rotated in a serial sequence through a VFD for positioning, or more than one reflector row may be rotated at the same time through a VFD for positioning. Similarly, when a VFD connected to motors driving a reflector rows is bypassed so that the motors are operating in direct drive, the reflector rows may be rotated in a serial manner, or more than one reflector row may be rotated at the same time. As indicated above, bypassing a VFD may enable rapid, simultaneous rotation of reflector elements to a storage position, with their reflective surfaces facing downward. In some arrays, two or more outer rows of a reflector field (or other reflector rows subject to high wind shear) may be configured to have their VFDs bypassed and rotated in direct drive operation at the same time to a storage position.
Solar energy collector systems including drives or drive systems such as those discussed above comprising one or more positional sensors, and those described in connection with
This disclosure is illustrative and not limiting. Further modifications will be apparent to one skilled in the art in light of this disclosure and such modifications are intended to fall within the scope of the appended claims. Each publication and patent application cited in the specification is incorporated herein by reference in its entirety as if each individual publication or patent application were specifically and individually put forth herein.
Claims
1. A solar energy collector system comprising:
- an elevated receiver comprising a solar radiation absorber;
- first and second reflector fields positioned on opposite sides relative to a center of the receiver;
- wherein:
- each reflector field comprises reflectors arranged into one or more parallel reflector rows extending generally in a direction parallel to a length of the receiver;
- the reflectors each comprise a reflective surface configured to direct incident solar radiation to form a line focus at the solar radiation absorber in the receiver;
- the reflectors are configured to be driven to at least partially track diurnal motion of the sun; and
- at least one reflector from the first and/or second reflector field has a focal length that is greater than a distance between the reflective surface of the at least one reflector and the solar radiation absorber.
2. The solar energy collector system of claim 1, wherein the one or more parallel reflector rows comprises an outer row, and the at least one reflector having a focal length that is greater than a distance between the reflective surface of the at least one reflector and the solar radiation absorber is positioned in the outer row.
3. The solar energy collector system of claim 1, wherein the at least one reflector has a focal length that is about 1% to about 15% greater than the distance between the reflective surface of the at least one reflector and the solar radiation absorber.
4. A solar energy collector system comprising:
- an elevated receiver comprising a solar radiation absorber;
- first and second reflector fields positioned on opposite sides relative to a center of the receiver;
- wherein:
- each reflector field comprises reflectors arranged into one or more parallel reflector rows extending generally in a direction parallel to a length of the receiver;
- the reflectors each comprise a reflective surface configured to direct incident solar radiation to the solar radiation absorber in the receiver; and
- the reflectors are configured to be driven to at least partially track diurnal motion of the sun,
- wherein the reflectors are arranged so that a focal length of each reflector is generally correlated with a distance between that reflector and the receiver.
5. A reflector for use in a solar energy collector system, the reflector comprising a reflective surface configured to direct incident solar radiation to form a line focus at a solar radiation absorber in an elevated receiver, and the reflector configured to be driven to at least partially follow diurnal motion of the sun, wherein the reflector has a focal length greater than a distance between the reflective surface of the reflector and the solar radiation absorber.
6. The reflector of claim 5, wherein the focal length of the reflector is about 1% to about 15% longer than the distance between the reflective surface of the reflector and the solar radiation absorber.
7. A solar energy collector system comprising:
- an elevated receiver extending in a longitudinal direction;
- a vertical support structure configured to support the elevated receiver; and
- first and second guy wires,
- wherein:
- the first guy wire is coupled to the vertical support structure at a first coupling point, extends laterally from the vertical support structure to a first anchoring point, and has a first resonance frequency between the first coupling point and the first anchoring point; and
- the second guy wire is coupled to the vertical support structure at a second coupling point, extends laterally from the vertical support structure to a second anchoring point, and has a second resonance frequency between the second coupling point and the second anchoring point, wherein the second resonance frequency is different from the first resonance frequency.
8. The solar energy collector system of claim 7, wherein the first resonance frequency differs from the second resonance frequency by at least about 20 percent.
9. A set of guy wires, the set comprising first and second guy wires, each of the first and second guy wires comprising a distal end and a proximal end, wherein:
- the distal end of the first guy wire is configured to be coupled to a distal end of a ground-anchored vertical support structure of a solar energy collector system at a first coupling point, and the proximal end of the first guy wire is configured to be anchored to the ground and/or to an anchoring structure at a first anchoring point;
- the distal end of the second guy wire is configured to be coupled to the distal end of the vertical support structure at a second coupling point, and the proximal end of the second guy wire is configured to be anchored to the ground and/or to an anchoring structure at a second anchoring point; and
- the first guy wire has a first resonance frequency between the first coupling and anchoring points when coupled to the vertical support structure at the first coupling and anchoring points, the second guy wire has a second resonance frequency between the second coupling anchoring points when coupled to the vertical support structure at the second coupling and anchoring points, and the first resonance frequency is different from the second resonance frequency.
10. The set of guy wires of claim 9, further comprising a third guy wire comprising a distal end and a proximal end, wherein the distal end of the third guy wire is configured to be coupled to the vertical support structure at a third coupling point, the proximal end of the third guy wire is configured to be anchored to the ground and/or to an anchoring structure at a third anchoring point, and the third guy wire has a third resonance frequency between the third coupling point and the third anchoring point that is different from at least one of the first and second resonance frequencies.
11. The set of guy wires of claim 9, wherein a length of the first guy wire between the first coupling point and the first anchoring point is different than a length of the second guy wire between the second coupling point and the second anchoring point.
12. The set of guy wires of claim 9, wherein a width of the first guy wire between the first coupling point and the first anchoring point is different than a width of the second guy wire between the second coupling point and the second anchoring point.
13. A solar energy collector system comprising:
- an elevated receiver comprising a solar radiation absorber;
- a plurality of vertical support structures configured to support the elevated receiver, the vertical support structures distributed longitudinally along a length of the elevated receiver; and
- an arrangement of longitudinal guy wires, wherein each longitudinal guy wire extends between two adjacent ones of the plurality of vertical support structures, and the vertical support structures and/or the arrangement of longitudinal guy wires are configured to stabilize the solar energy collector system and to accommodate longitudinal thermal expansion of one or more components of the elevated receiver.
14. The solar energy collector system of claim 13, wherein the arrangement of longitudinal guy wires comprises a density of longitudinal guy wires that decreases as a distance from a longitudinal center of the elevated receiver increases.
15. The solar energy collector system of claim 13, wherein the arrangement of longitudinal guy wires comprises a first set of generally parallel single longitudinal guy wires, each single longitudinal guy wire in the first set extending generally in a first diagonal direction between two adjacent ones of the plurality of vertical support structures.
16. The solar energy collector system of claim 15, wherein:
- the arrangement of longitudinal guy wires further comprises a second set of generally parallel single longitudinal guy wires, each single longitudinal guy wire in the second set extending generally in a second diagonal direction between two adjacent ones of the plurality of vertical support structures; and
- the first set and second sets of longitudinal guy wires are positioned on opposite sides relative to a longitudinal center of the receiver.
17. A method of installing a linear Fresnel solar reflector system, the method comprising:
- arranging a plurality of reflectors into reflector rows;
- providing a receiver body comprising a receiver channel, the receiver channel comprising first and second sidewalls and an aperture each extending along a length of the receiver channel;
- arranging a plurality of solar radiation absorbing tubes lengthwise in the receiver channel;
- inserting a window into the receiver channel in a direction transverse to the length of the receiver channel;
- securing the window over the aperture so that the window forms a junction with each of the first and second sidewalls of the receiver channel to form a cavity housing the solar radiation absorbing tubes;
- orienting the receiver body so that the length of the receiver channel is generally parallel to the reflector rows;
- elevating the receiver body comprising the receiver channel, the solar radiation absorber tubes, and the window to an installed vertical receiver position that is above the plurality of reflectors; and
- aligning the plurality of reflectors so that each reflector directs incident solar radiation through the window to be at least partially incident on one or more of the solar absorber tubes when the receiver body is in the installed vertical receiver position.
18. The method of claim 17, comprising securing the window to the receiver channel with fasteners before elevating the receiver body to the installed vertical receiver position.
19. The method of claim 17, wherein elevating the receiver body comprises:
- anchoring a proximal end of a jointed vertical support structure to the ground;
- angling a distal end of the jointed vertical support structure toward the ground;
- securing the receiver body to the distal end of the jointed vertical support structure; and
- applying lateral force to the distal end of the jointed vertical support structure to elevate the receiver body.
20. The method of claim 17, comprising applying lateral force to the distal end of the jointed vertical support structure with a tether.
21. The method of claim 18, further comprising threading the tether through one or more pulleys to control the application of lateral force to the distal end of the jointed vertical support structure.
22. A vertical support structure, comprising:
- a proximal end configured to be anchored to the ground;
- a distal end configured to be coupled to an elevated receiver in a solar energy collector system; and
- a first joint, wherein the first joint is configured to: allow the distal end of the vertical support structure to be angled toward the ground for coupling the receiver thereto at or near ground level while the proximal end of the vertical support structure is anchored to the ground; and allow the distal end of the vertical support structure to be elevated with the application of lateral force to the distal end of the vertical support structure, so that a receiver coupled thereto can be elevated to a vertical installed receiver position.
23. The vertical support structure of claim 22, comprising a second joint positioned distally relative to the first joint, wherein:
- the second joint can be flexed independently from the first joint;
- the second joint is configured to: allow the distal end of the vertical support structure to be angled more toward the ground than the first joint while the proximal end of the vertical support structure is anchored to the ground; and allow the distal end of the vertical support structure to be elevated with application of lateral force to the distal end of the vertical support structure, so that the receiver coupled thereto can be elevated to the vertical installed receiver position.
24. The vertical support structure of claim 22, further comprising a tether coupled to the distal end of the vertical support structure, wherein the tether is configured to apply lateral tension to the distal end of the vertical support structure to elevate a receiver coupled thereto.
25. The vertical support structure of claim 24, further comprising one or more pulleys, wherein the tether is configured to be threaded through the one or more pulleys to guide the position of the tether as lateral tension is applied to the distal end of the vertical support structure.
26. A method for making a carrier frame for supporting reflector elements in a linear Fresnel solar reflector system, the method comprising:
- providing first and second platforms, each platform comprising a first end and an opposite second end;
- providing a first reflector support comprising one or more attachment tabs affixed to the first reflector support;
- fixing the first reflector support to the second end of the first platform;
- temporarily coupling the first reflector support to the first end of the second platform with the one or more attachment tabs so that the first and second platforms each extend from opposite sides of the first reflector support; and
- aligning the second platform with the first platform with the one or more attachment tabs.
27. The method of claim 26, further comprising fixing the first end of the second platform to the first reflector support after aligning the first platform with the second platform.
28. The method of claim 26, further comprising providing second and third reflector supports, wherein the second reflector support is coupled to the first end of the first platform so that the first platform is supported between the first and second reflector supports, and the third reflector support is coupled to the second end of the second platform so that the second platform is supported between the first and third reflector supports.
29. The method of claim 26, comprising aligning the first platform with the second platform to within about 5 mm.
30. A carrier frame for supporting reflector elements in a linear Fresnel reflector system, the carrier frame comprising:
- first and second platforms, each platform comprising first and second ends; and
- a first reflector support comprising a first side and a second opposite side, and at least one attachment tab affixed to the first reflector support, wherein:
- the second end of the first platform is fixed to the first side of the first reflector support;
- the first end of the second platform is removably attached to the first reflector support with at least one attachment tab, so that the first and second platforms extend from opposite sides of the first reflector support; and
- the at least one attachment tab is configured to allow alignment of the second platform relative to the first platform and to allow securing of the second platform to the first reflector support in an aligned position.
31. The carrier frame of claim 30, further comprising second and third reflector supports, wherein the second reflector support is fixed to the first end of the first platform so that the first platform is supported between the first and second reflector supports, and the third reflector support is fixed to the second end of the second platform so that the second platform is supported between the first and third reflector supports.
32. The carrier frame of claim 30, wherein the attachment tab comprises a threaded hole configured to accept a threaded bolt coupled to the second platform.
33. The carrier frame of claim 30, wherein the attachment tab is configured to allow rotation and/or translation of the second platform to align the second platform with the first platform.
34. A method for installing an elevated receiver into a solar energy collector system, the method comprising:
- anchoring a vertical support structure to the ground; and
- lifting a receiver with a hoist coupled to the vertical support structure; and
- coupling the receiver to the vertical support structure to install the receiver in the solar energy collector system.
35. The method of claim 34, wherein the vertical support structure comprises a shelf, and coupling the receiver to the vertical support structure comprises supporting the receiver on the shelf.
36. The method of claim 34, comprising:
- anchoring a row of vertical support structures to the ground, at least one of the vertical support structures comprising a hoist;
- positioning an elongated receiver at or near ground level along the row of vertical support structures;
- lifting the elongated receiver with the hoist; and
- coupling the elongated receiver to the row of vertical support structures to install the receiver in the solar energy collector system.
37. The method of claim 34, comprising removing the hoist after the receiver has been installed.
38. A vertical support structure for use in a solar energy collector system, the vertical support structure comprising:
- at least one post configured to be anchored to the ground;
- a hoist configured to lift an elevated receiver; and
- at least one mounting member configured to support the receiver in an elevated installed position.
39. The vertical support structure of claim 38, wherein the at least one mounting member comprises a shelf.
40. The vertical support structure of claim 38, comprising two posts, each post configured to be coupled to the ground, wherein the posts are angled toward each other and interconnected at or near a peak of the vertical support structure.
41. The vertical support structure of claim 38, wherein the hoist is mounted to an auxiliary portion of the vertical support structure, and the auxiliary portion is configured to be removed after the receiver is installed.
42. The method of claim 17, wherein elevating the receiver body to an installed vertical receiver position comprises:
- anchoring at least one post of a vertical support structure to the ground;
- elevating the receiver body with a hoist coupled to the vertical support structure; and
- coupling the elevated receiver body to the vertical support structure.
Type: Application
Filed: Feb 5, 2008
Publication Date: Mar 5, 2009
Applicant: Ausra, Inc. (Palo Alto, CA)
Inventors: David R. Mills (Palo Alto, CA), Philipp Schramek (Starnberg), David B. Degraaff (Mountain View, CA), Peter L. Johnson (Mountain View, CA), Alexander Hoermann (Menlo Park, CA), Lars R. Johnson (Mountain View, CA)
Application Number: 12/012,920
International Classification: F24J 2/10 (20060101); F16G 11/00 (20060101); B23P 19/04 (20060101); F24J 2/46 (20060101);