Patent Grant
8850755
This invention is in the field of solar thermal power production. This invention relates generally to a solar trough and components thereof for collection, concentration, and conversion of solar energy to heat or electricity.
Solar power generation currently represents a small part of the total global electricity supply; however, there is an enormous potential for power generation worldwide using solar concentration techniques. Solar thermal power generation has advantages over solar power generation using photovoltaics including eliminating the need for large quantities of crystalline silicon for production of photovoltaic cells.
One technique for solar power generation utilizes arrays of reflective troughs for concentration of incident solar radiation, by reflection, onto receivers capable of efficiently converting the solar radiation to heat for subsequent utilization, for example power generation. Linear troughs having parabolic cross-sections are amongst the preferred shapes for solar troughs and various trough designs exist.
For example, U.S. Pat. No. 4,596,238 discloses a solar trough having a generally rectangular flexible sheet with a reflective surface. The sheet is formed into a concentrating shape by a pair of identical form members which are positioned at parallel edges of the flexible sheet and include a tensioning means positioned between the form members.
U.S. Pat. No. 4,611,575 also discloses a solar trough which utilizes parabolic ribs and cross members to form a rigid structure and reflective sheets formed of steel and having adhesively bonded reflective film thereon. The reflective sheets are formed into parabolic shapes by attachment to joining members attached to the parabolic ribs.
U.S. Pat. No. 5,964,216 discloses a trough-type parabolic concentrator which utilizes a reflector plate bent into a trough shape and a support structure made of a plurality of wooden frames. The wooden frames are joined together using screws to make a single parabolic segment and guide rails are attached to two adjacent parabolic segments to force the reflector plates to take a parabolic shape. The reflector plates are secured against slipping by wooden or metal stops placed at the outer ends of a segment.
U.S. Pat. No. 4,372,027 discloses a monocoque parabolic trough-type solar concentrator having reflective sheets attached to parabolic bows. Also disclosed is a roll-forming method for attaching a reflective laminate to the surface of the sheets of the monocoque trough.
One disadvantage of the solar troughs described above is that the reflective sheets are generally permanently attached to the supporting and/or shaping structure. In order to repair or replace the reflective sheets, the trough structures must undergo a significant amount of disassembly, increasing repair and assembly time and costs.
Provided herein are solar concentrators having reflective sheets which are slidably insertable and/or removable for quick installation, construction, removal, repair, and/or replacement. Also provided are solar concentrators having reflective sheets under tension. Further provided herein are methods for constructing solar collectors. In another aspect, provided herein are guide rails for guiding and/or retaining slidably removable reflective sheets.
In a first aspect, provided herein is a guide rail for directing and retaining a slidably removable reflective sheet. A guide rail of this aspect comprises a rail body having a longitudinal axis and one or more longitudinal channels sized and shaped for guiding and retaining a longitudinal edge of one or more slidably removable reflective sheets. In a specific embodiment, a guide rail comprises a rail body having a longitudinal axis and one or more longitudinal channels sized and shaped for guiding and retaining a longitudinal hook edge or a longitudinal hemmed edge of one or more slidably removable reflective sheets. In an embodiment, a guide rail comprises a rail body having a longitudinal axis and one or more longitudinal channels having retaining shapes. In a specific embodiment, the longitudinal channels for guiding and retaining the longitudinal edge of one or more slidably removable reflective sheets comprise an outer channel portion and an inner channel portion wider than the outer channel portion.
Longitudinal channels having a retaining shape or such inner and outer portions are useful, for example, for guiding and retaining hook or hemmed longitudinal edges of one or more slidably removable reflective sheets. In specific embodiments, the inner portion of such a channel has a depth selected from about 0.080″ to about 0.250″, or more preferably a depth selected from about 0.090″ to about 0.175″, or even more preferably a depth selected from about 0.100″ to about 0.125″. In specific embodiments, the inner portion of such a channel has a width selected from about 0.270″ to about 1.000″, or more preferably a width selected from about 0.500″ to about 0.800″, or even more preferably a width selected from about 0.650″ to about 0.700″. In specific embodiments, the outer portion of such a channel has a depth selected from about 0.050″ to about 0.125″, more preferably a depth selected from about 0.068″ to about 0.110″, or even more preferably a depth selected from about 0.085″ to about 0.100″. In specific embodiments, the outer portion of such a channel has a width selected from about 0.040″ to about 0.250″, more preferably a width selected from about 0.100″ to about 0.225″, or even more preferably a width selected from about 0.150″ to about 0.215″.
In an embodiment, a guide rail comprises a rail body having upper and lower surfaces and further comprises a pair of longitudinal tabs positioned on the upper surface for retaining a slidably removable reflective strip. In another embodiment, a guide rail comprises a longitudinal channel sized and shaped for attachment to a supporting rib. In a specific embodiment, the supporting rib has a parabolic or substantially parabolic longitudinal shape and forces the guide rail to adopt a parabolic or substantially parabolic longitudinal shape. In specific embodiments, a supporting rib has a thickness selected from 0.040″ to 0.400″, or more preferably a thickness selected from 0.060″ to 0.350″, or even more preferably a thickness selected from 0.120″ to 0.300″. In a specific embodiment, a guide rail of this aspect has a longitudinal channel sized and shaped for attachment to a supporting rib positioned on the lower surface of a guide rail having lower and upper surfaces.
In an embodiment, the guide rails comprise a single piece of material formed by extrusion, for example steel, aluminum or plastic. In another embodiment, a guide rail has a rail body comprising one or more pieces, for example a top piece and a bottom piece. Guide rails formed of multiple pieces are useful, for example, when it is not possible to form by extrusion a guide rail having a desired cross-sectional shape in a single piece. In a specific embodiment, the top piece and the bottom piece respectively define top and bottom surfaces of the one or more longitudinal channels for guiding and/or retaining the longitudinal edge of one or more slidably removable reflective sheets.
In an embodiment, a guide rail comprises a main body and interlocking pieces. The main body comprises a longitudinal channel and the interlocking pieces serve to retain one or more slidably removable reflective sheets in the channel. In an exemplary embodiment, a mechanical mechanism is optionally used to insert the interlocking pieces. An advantage to this embodiment is that no edge preparation is needed on the slidably removable reflective sheet.
In an embodiment, a guide rail comprises one or more retaining means for securing a slidably removable reflective sheet. Useful retaining means comprise, for example, a retaining pin and mating hole for insertion thereof or a rail member positioned transversely to the guide rail. In a specific embodiment, a transverse rail member is attached to the transverse edges of a slidably removable reflective sheet, for example by a clamping mechanism. Transverse rail members may also be used for securing the slidably removable reflective sheet into place by attachment of the transverse rail at one or more points to a guide rail and/or supporting rib.
In another aspect, the guide rails can be used for forming an assembly comprising a guide rail and a slidably removable reflective sheet having a longitudinal edge retained in a longitudinal channel of the guide rail. In a specific embodiment, the slidably removable reflective sheet comprises a sheet of material, for example a metal, and preferably aluminum or steel. Slidably removable reflective sheets useful with various embodiments of the present invention have one or more reflective surfaces, for example surfaces capable of reflecting a substantial portion of the incident light. In an embodiment a useful reflective surface is capable of withstanding long-term exposure to the elements. In an embodiment, a slidably removable reflective sheet comprises a reflective film, for example ReflecTech™ silvered film, or a polished or anodized metal surface. In specific embodiments, a slidably removable reflective sheet has a thickness selected from about 0.020″ to about 0.080″, or more preferably a thickness selected from about 0.025″ to about 0.065″, or even more preferably a thickness selected from about 0.030″ to about 0.055″. In a specific embodiment, a slidably removable reflective sheet comprises a reflective film adhesively attached to a sheet of material.
In an embodiment, a reflective assembly comprises a guide rail and a first slidably removable reflective sheet having two longitudinal edges positioned in one or more longitudinal channels of the guide rail and generally positioned over the upper surface of the guide rail. In a specific embodiment, the first slidably removable reflective sheet further allows the channels of the guide rail to comprise a retaining shape. In a specific embodiment, a reflective assembly further comprises one or more additional slidably removable reflective sheets positioned in the channel or channels of the guide rail, wherein the one or more additional slidably removable reflective sheets are retained by the first slidably removable reflective sheet. In an alternative embodiment, the first slidably removable reflective sheet is replaced by one or more clips, positioned over the upper surface of the guide rail to allow the channels of the guide rail, combined with the one or more clips, to comprise a retaining shape.
In another aspect, the present invention provides a reflective assembly for a solar collector comprising a pair of supporting ribs, a pair of guide rails, one mounted on each supporting rib, for directing longitudinal edges of one or more slidably removable reflective sheets and one or more slidably removable reflective sheets having longitudinal edges mounted within longitudinal channels of the pair of guide rails. A specific reflective assembly embodiment further comprises one or more additional supporting ribs, guide rails, and slidably removable reflective sheets. Such a reflective assembly is useful, for example, as it can have a longer transverse length.
In an embodiment, the guide rails of the reflective assembly are shaped so as to define an optical surface of the one or more slidably removable reflective sheets, for example an optical surface that reflects a substantial portion of incident light to a solar receiver. In an embodiment, a useful guide rail shape is a linear shape, so as to define a planar optical surface. In another embodiment, a useful guide rail shape is a substantially parabolic shape, so as to define a trough shaped optical surface. In a specific embodiment, the supporting ribs span an entire length of the guide rails. In an embodiment, the supporting ribs comprise multiple pieces that together span the length of the guide rails. In an embodiment, a longitudinal edge of one or more of the reflective sheets is a hemmed longitudinal edge. In another embodiment, a longitudinal edge of one or more of the reflective sheets is a longitudinal hook edge.
In some embodiments, the longitudinal hook and/or hemmed edges of a slidably removable reflective sheet are fabricated by a roll forming process. U.S. Provisional Patent Application 61/144,703 filed on Jan. 14, 2009, herein incorporated by reference in its entirety, describes methods for manufacturing hook and hemmed longitudinal edges through roll forming.
In an aspect, at least one of the one or more slidably removable reflective sheets of the reflective assembly is under tension, for example by application of a tensile force by the guide rails. In a specific embodiment of this aspect, the reflective assembly of this aspect further comprises one or more springs attached to at least one of the pair of supporting ribs for placing the one or more slidably removable reflective sheets under tension. In specific embodiment, the reflective assembly further comprises one or more compliant features, for example for application of a tensile force to the one or more slidably removable reflective sheets. In a related embodiment, the one or more slidably removable reflective sheets comprise one or more compliant features. In another embodiment, the distance between the pair of supporting ribs is not fixed and is adjustable. This is useful, for example, as the one or more slidably removable reflective sheets may be placed under tension by increasing the distance between the pair of supporting ribs supporting each slidably removable reflective sheet.
In an embodiment, a reflective assembly further comprises a transverse rail member mounted between the pair of supporting ribs for attaching to, supporting, or retaining one or more transverse edges of one or more of the slidably removable reflective sheets, for example by a clamping mechanism. In a specific embodiment, the transverse rail member has one or more transverse channels for retaining one or more transverse edges of one or more of the slidably removable reflective sheets. Transverse rail members include embodiments comprising a single rail member and embodiments comprising two adjoining rail members, for example fastened together by interlocking features, nuts and bolts, screws, clamps, clips or other attachment means known in the art.
In an embodiment, the transverse rail member is positioned to attach to, support, or retain one or more transverse edges of one or more slidably removable reflective sheets at a rim of the reflective assembly. In another embodiment, the transverse rail member is positioned to attach to, support, or retain one or more transverse edges of one or more slidably removable reflective sheets at a longitudinally interior position of the reflective assembly. In another embodiment, the transverse rail member extends beyond the pair of supporting ribs and/or guide rails for attaching to, supporting, or retaining one or more transverse edges of one or more slidably removable reflective sheets of an adjacent reflective assembly.
In an embodiment, the transverse rail member comprises a first portion positioned on a first surface of the one or more slidably removable reflective sheets and one or more second portions each positioned between a pair of supporting ribs on a second surface, opposite the first surface, of the one or more slidably removable reflective sheets. In a specific embodiment, the transverse rail member first portion extends across and/or attaches to one or more guide rails by one or more attachment means. Useful attachment means include bolts, screws, clamps, or other attachment methods known in the art. In a specific example, T-bolts or other bolts are inserted into longitudinal channels of one or more guide rails for attaching the transverse rail first and/or second portion to one or more guide rails. In alternate embodiments, other attachment means are used in place of the T-bolts. Attaching the transverse rail member to the guide rails may result in fewer distortions to the optical surface of the slidably removable reflective sheets compared to other transverse rail member embodiments.
For some embodiments, the transverse rail first and second portions retain the one or more transverse edges of the one or more slidably removable reflective sheets by a clamping mechanism. For example, the transverse rail members may further comprise one or more clips for clamping the transverse rail first and second portions onto the one or more transverse edges of the one or more slidably removable reflective sheets. In a specific embodiment, the transverse rail member includes grooves for attaching the clips. In another embodiment, screw fasteners or bolts and nuts may be used to clamp the transverse rail first and second portions onto the one or more transverse edges of the one or more slidably removable reflective sheets.
The transverse rail member may also comprise one or more self-locating features for properly aligning the transverse rail member to the guide rails, supporting ribs, slidably removable reflective sheets, or other portions of the reflective assembly. In a specific embodiment, self-locating features are useful for aligning first and second portions of a transverse rail member to one another.
In another aspect, provided herein is a reflective trough comprising a supporting structure, a plurality of supporting ribs mounted on the supporting structure, a plurality of guide rails, at least one guide rail mounted on each supporting rib, and a plurality of slidably removable reflective sheets having longitudinal edges mounted within channels of the guide rails. In a preferred embodiment of this aspect, the reflective trough is a parabolic trough.
In an embodiment, the supporting structure, plurality of supporting ribs, and plurality of guide rails are shaped so as to give the slidably removable reflective sheets an optical surface having a trough shape. In an embodiment, the optical surface reflects a substantial portion of the incident light to a solar receiver. In a specific embodiment, the supporting structure comprises a space frame. In a specific embodiment, the supporting ribs are mounted on the supporting structure at regular intervals. In another embodiment, the supporting ribs are mounted on the supporting structure at a variety of intervals.
In an embodiment, the supporting ribs and/or guide rails define optical surfaces of the plurality of slidably removable reflective sheets, for example optical surfaces that each reflect a substantial portion of the incident light to a solar receiver. In an embodiment of this aspect, a reflective trough further comprises a solar receiver mounted at a point of substantially optimal energy capture for absorbing a substantial portion of the incident light. In a specific embodiment, a solar receiver is mounted along a transverse focal line of the reflective trough or a line of substantially optimal energy capture.
In an embodiment, a transverse rail member is useful with reflective assemblies and troughs, for example for attaching to, supporting, or retaining a transverse edge of a slidably removable reflective sheet. In an embodiment, a transverse rail member is useful for increasing the rigidity of the slidably removable reflective sheets along the transverse direction, for example to aid in defining the optical surface of the slidably removable reflective sheets and/or to aid in the assembly of a reflective assembly or a reflective trough.
In an embodiment, the transverse rail members comprise one or more transverse channels. In an embodiment, a transverse rail member attaches to, supports or retains a transverse edge of a single slidably removable reflective sheet. In another embodiment, a transverse rail member extends across at least three supporting ribs for attaching to, supporting, or retaining transverse edges of at least two slidably removable reflective sheets. Transverse rail members may be positioned at rim of the reflective trough or at an interior position of the reflective trough.
As with the reflective assemblies described above, some reflective trough embodiments may further comprise one or more compliant features. In an embodiment, the one or more compliant features apply tension to at least one of the plurality of slidably removable reflective sheets along a transverse direction. In an embodiment, the supporting structure provides the compliant features. In another embodiment, the compliant features are provided by at least one of the slidably removable reflective sheets. The reflective troughs may also comprise one or more compression and/or extension springs for applying tension to at least one of the plurality of slidably removable reflective sheets along a transverse direction. In addition to one or more springs, the reflective troughs of this aspect may further comprise one or more bolts or threaded rods passing through the center of at least one of the one or more springs.
A reflective trough embodiment may also further comprise means for translating at least one of the plurality of supporting ribs in a transverse direction. For example, the reflective trough may comprise one or more rib translation rails. By increasing the distance between the supporting ribs which support each slidably removable reflective sheet, tension may be applied to one or more of the slidably removable reflective sheets.
In another aspect, the present invention provides a method for constructing a reflective solar assembly. A method of this aspect comprises the steps of attaching one or more guide rails to one or more supporting ribs, and sliding opposite longitudinal edges of one or more slidably removable reflective sheets into longitudinal channels of the guide rails attached to transversely adjacent ribs. In a specific method of this aspect, transverse rail members are attached to transverse edges of the slidably removable reflective sheets before sliding the longitudinal edges of the slidably removable reflective sheets into the longitudinal channels of the guide rails. According to some embodiments, first attaching transverse rail members to the reflective sheets eases installation into the longitudinal channels and prevents the reflective sheets from sagging or bowing. In another embodiment, the reflective sheets are installed before the transverse rail members are attached, using temporary transverse supports which are then removed before the final transverse rail members are installed.
In order to place at least one of the slidably removable reflective sheets under tension along a transverse direction, a method of this aspect further comprises the step of increasing the transverse spacing between adjacent ribs. In a specific method of this aspect, the supporting ribs are first attached to a support structure. In a method of this aspect, increasing the transverse spacing between transversely adjacent ribs aids in seating at least one of the one or more slidably removable reflective sheets more firmly on the guide rails.
In order to place at least one of the slidably removable reflective sheets under tension along a transverse direction, in an embodiment, the support structure comprises one or more compliant features. In an embodiment, the support structure comprises one or more springs and/or flexure sections for the application of tension to at least one slidably removable reflective sheet. In an embodiment, the support structure comprises means for translation of at least one of the plurality of supporting ribs in a transverse direction, for example one or more rib translation rails.
Without wishing to be bound by any particular theory, there can be discussion herein of beliefs or understandings of underlying principles relating to the invention. It is recognized that regardless of the ultimate correctness of any mechanistic explanation or hypothesis, an embodiment of the invention can nonetheless be operative and useful. It will be evident to one having skill in the art that the accompanying drawings may not be to scale to better illustrate certain aspects of the invention.
In general the terms and phrases used herein have their art-recognized meaning, which can be found by reference to standard texts, journal references and contexts known to those skilled in the art. The following definitions are provided to clarify their specific use in the context of the invention.
“Guide rail”, “rail body”, and “guide rail body” interchangeably refer to a rail structure having a channel (also referred herein as a track, groove, or slot) running along the rail structure used for guiding, directing, retaining, attaching, capturing, and/or shaping a sheet or panel. In some embodiments a guide rail is a separate member attached to another structure, such as a rib or other supporting structure. In other embodiments, a guide rail can refer to an object having a channel contained within the object, for example a channel cut into or formed in a supporting rib or support structure.
“Longitudinal,” “longitudinal direction,” or “longitudinal axis” refers to a direction or axis parallel to the long axis of a guide rail, for example a guide rail of a reflective assembly or reflective trough. The longitudinal axis can include embodiments where the axis is linear or non-linear, such as parabolic or semi-circular. For example, the longitudinal axis of a parabolic or otherwise curved guide rail is understood to run along the guide rail in a continuously tangential manner. The longitudinal axis of a sheet or panel is understood to be the axis of the sheet or panel parallel to the longitudinal axis of any guide rail or supporting rib which is attached to, supporting, retaining, guiding, or directing the sheet or panel.
“Transverse,” “transverse direction,” or “transverse axis” refers to a direction or axis perpendicular to the longitudinal axis of a guide rail. In some embodiments a transverse axis is an axis which runs along the rim of a reflective trough, or an axis which runs along the length of a solar receiver of a parabolic trough.
“Channel” refers to a recessed region of an object or body. A channel may have one or more depths, one or more widths, and/or one or more lengths. A channel also refers to features referred to as a track, a groove, and/or a slot. In an embodiment, a longitudinal channel refers to a recessed region of an object having a longitudinal dimension. In an embodiment, a channel is formed in an object by removing material from the body of the object. In another embodiment, a channel is formed in an object during the construction or formation of the object, for example by molding or extrusion. In another embodiment, a channel is formed in an object after construction or formation of the object, for example by stamping or machining.
“Slidably insertable” or “slidably removable” refers to the ability of an object which is not permanently fixed to another structure to be easily installed or removed from a retained, supported, or attached position on the structure by means of a relative translation of the object and the structure in a sliding motion.
“Reflective sheet” refers to a sheet, panel, or film having a highly reflective surface for reflection of incident light. In an embodiment, a reflective sheet comprises a thin sheet of material, for example a metal sheet, preferably aluminum or steel, with a reflective film thereon having a reflectivity acceptable for use in solar collectors (e.g., ReflecTech™ silvered film). In an embodiment, a reflective sheet comprises a metal sheet having a polished or anodized surface. In an embodiment, a reflective sheet comprises a reflective film.
“Supporting rib” refers to a stiff longitudinal member that supports another object along the longitudinal direction and is capable of transferring the weight of the object to the ground or another supporting structure. In some embodiments a supporting rib has a precisely shaped dimension, for example a linear or parabolic surface, which can be used to define or force the shape of another object attached to or supported by the supporting rib. In an embodiment, a plurality of supporting ribs are used for supporting the weight of a sheet of material positioned across the plurality of supporting ribs. Supporting ribs may also apply tensile forces to structures supported by multiple supporting ribs. Supporting ribs are also useful for transferring environmental forces to the ground or a supporting structure, for example, forces due to wind or snow loads on a sheet of material supported by the supporting rib.
“Supporting structure” or “support structure” refers to a rigid device used for supporting another object, transferring the weight of the object to the ground, and/or holding or controlling the position of the object. In an embodiment, a supporting structure is comprised of a plurality of rigid members. In an embodiment, a supporting structure is used to generally define the shape of an object which is supported by the supporting structure.
“Retaining shape” refers to the shape of a longitudinal channel of a guide rail useful for retaining a longitudinal edge of a slidably removable reflective sheet such that the slidably removable reflective sheet can not be removed or escape from the longitudinal channel by a translation or sequence of translations other than translation substantially along the longitudinal direction. In a specific embodiment, a retaining shape includes a shape pair or matching shapes of a longitudinal channel of a guide rail and a longitudinal edge of a reflective sheet. In an embodiment, a retaining shape includes an enclosing shape, i.e., a retaining shape for surrounding a longitudinal edge of a reflective sheet. In some embodiments, the longitudinal edge of a slidably removable reflective sheet may be removed or escape from a longitudinal channel having a useful retaining shape by a rotation of the reflective sheet or by translation along the longitudinal direction. In certain embodiments, a longitudinal channel having a retaining shape additionally maintains a slidably removable reflective sheet in a shape prescribed by the shape of the guide rail.
“Retain” or “capture” refers to the ability of one object to hold another object in place, for example, to prevent relative movement of the objects in at least one direction. In an embodiment, an object is retained by another object by mechanical friction. In an embodiment, an object is retained by another object by a physical restraint, for example a retaining pin. In an embodiment, an object is retained by another object by a clamping mechanism
“Hemmed edge” refers to the end of an object which is rolled or folded onto itself. A hemmed edge can also refer to the end of an object which is rolled or folded over another object to create a wide or enlarged and relatively stiff edge. In an embodiment, the edge of a reflective sheet is rolled onto itself to form a hemmed edge; such a hemmed edge can be used to retain the reflective sheet in a channel of a guide rail. In a specific embodiment, a hemmed edge comprises a single hem, for example the edge of an object rolled or folded onto itself once. In another specific embodiment, a hemmed edge comprises a double hem, for example the edge of an object rolled or folded onto itself twice. In a specific embodiment, a hemmed edge is manufactured through roll forming.
“Hook edge” refers to the end of an object which is curved to form a hook-like shape. In an embodiment, the cross-section of an object with a hook edge resembles the general shape of a hook. In an embodiment, the edge of a reflective sheet is curled, bent or folded over itself to form a continuous hook edge. In an embodiment, a hook edge of a reflective sheet can be captured or retained in a channel of a guide rail. In a specific embodiment, a hook edge is manufactured through roll forming.
“Longitudinal tabs” refers to longitudinal structures which extend off of the main body of a longitudinal object. In an embodiment, a longitudinal tab is used for capturing the longitudinal edge of a sheet or strip.
“Not fixedly attached” refers to the arrangement of a plurality of objects such that the objects are not permanently or temporarily attached to one another in any mechanical way other than friction. In an embodiment, objects which are not fixedly attached to one another can be retained or captured. In an embodiment, objects which are not fixedly attached can be retained by mechanical friction.
“Mechanically attached” refers to the arrangement of a plurality of objects such that the objects are attached to one another at one or more attachment points by any mechanical attachment means, for example screws, bolts or retaining pins, and can be separated by removing the mechanical attachment means. In a specific embodiment, a plurality of objects are attached to one another by clamping.
“Optical surface” refers to a precisely machined, arranged, formed, patterned, and/or shaped surface for focusing, reflecting, or absorbing incident light.
“Substantial portion” refers to a percentage greater than or equal to 50%.
“Solar receiver” refers to a component capable of absorbing incident solar radiation. In an embodiment, a solar receiver is positioned at a specific location for absorbing a substantial portion of solar radiation which is reflected from one or more reflective sheets.
“Point of substantially optimal energy capture” and refers to positions of a solar receiver wherein the solar receiver is mounted such that a substantial portion of the light incident on a reflecting surface is reflected onto the solar receiver. In a specific embodiment, the point of substantially optimal energy capture is the position of the solar receiver wherein the solar receiver receives and/or absorbs the maximum or near the maximum amount of reflected light. In a specific embodiment, a solar receiver mounted at a point of substantially optimal energy capture absorbs a substantial portion of the light incident on the surface of the solar receiver.
In a reflective trough, a “line of substantially optimal energy capture” is a successive series of points of substantially optimal energy capture corresponding to a series of points along the reflective trough.
“Reflective assembly” refers to an assembly comprising one or more reflective sheets, one or more guide rails, and one or more supporting ribs. In some embodiments, the one or more guide rails and one or more supporting ribs comprise a unitary structure. Depending on the specific application, a reflective assembly can have a parabolic, planar, or other shape known to the art. In an embodiment, multiple reflective assemblies are constructed and/or positioned adjacent to and/or adjoining one another to form a long reflective structure.
“Rib translation rail” refers to a structure which allows for the translation of a supporting rib. In an embodiment, a rib translation rail allows for motion of a supporting rib in a transverse direction and allows for adjusting the distance between adjacent ribs, and/or for application of tension to a sheet of material supported across multiple supporting ribs.
“Reflective strip” refers to a narrow (i.e., longer than it is wide) sheet, panel, or film having a reflective surface for reflection of incident light. In an embodiment, a reflective strip comprises a sheet of material, for example a metal, preferably aluminum or steel, with a reflective film thereon having a reflectivity acceptable for use in solar collectors (e.g., ReflecTech™ silvered film). In an embodiment, a reflective strip comprises a metal sheet having a polished or anodized surface. In an embodiment, a reflective strip comprises a reflective film.
“Compliant feature” refers to a portion of a structure which has a stiffness smaller than that of the surrounding structure, resulting in a feature which can withstand an applied force with a motion of the feature, for example a bending motion.
“Flexure section” refers to a portion of a structure capable of undergoing a bending or flexing motion in a reversible manner. A flexure section can also refer to a portion of a structure having a stiffness smaller than that of other portions of the structure. In an embodiment, a flexure section can be incorporated into a structure to give the structure a means for applying, resisting, or withstanding a force or tension applied to the structure.
“Inner portion” refers to the part of an object which generally faces towards or is located closest to the center of an object. The term “inner portion” may also refer to the internal part of an object. In an embodiment, the inner portion of a channel is the deepest or most interior portion of the channel.
“Depth” refers to a distance dimension of an object or a region within a body, for example a channel of a guide rail, relating to the distance of the object or region from the surface of the body.
“Outer portion” refers to the part of an object which generally faces away from or is located furthest from the center of an object. The term “outer portion” may also refer to the external part of an object. In an embodiment, the outer portion of a channel is the shallowest or external portion of the channel or the portion of a channel which connects with the surface of a body. In an embodiment, the outer portion and inner portions of a channel are further distinguished from one another based on a change in dimension (e.g., width) of the channel. In an embodiment, the inner portion of a channel has a wider width than the outer portion of the channel.
“Width” refers to a distance dimension of an object or region, for example the transverse dimension of a channel of a guide rail.
“Rim” as used with respect to a reflective trough or reflective assembly refers to the transverse edge of the reflective trough or reflective assembly.
“Self-locating” refers to the ability of an object to align itself to another object. In some embodiments, features of two objects allow the objects to be self-locating to one another.
In an aspect, the present invention provides solar collectors useful for concentrating solar energy as an energy producing device. In an aspect, the solar collectors described herein comprise one or more guide rails for guiding, retaining, and/or shaping a slidably removable reflective sheet. A guide rail embodiment of the present invention comprises a longitudinal rail body having one or more longitudinal channels for guiding and/or retaining a longitudinal edge of one or more slidably removable reflective sheets.
In one embodiment, a guide rail of the present invention comprises a rail body having a longitudinal axis and a first longitudinal channel sized and shaped for guiding and retaining a longitudinal hook edge or a longitudinal hemmed edge of one or more slidably removable reflective sheets. In a specific embodiment, the first longitudinal channel comprises an outer portion and an inner portion wider than the outer portion.
In one embodiment, guide rails are made of a single material, for example steel, aluminum or plastic, and in a specific embodiment are made by extrusion, although they can be made by other methods. Embodiments are contemplated which include multiple materials, for example, a guide rail which includes a slip coating comprising plastic, Teflon®, or other coating, for decreasing the friction along the longitudinal direction between the guide rail and a slidably removable reflective sheet being installed or removed from a longitudinal channel of the guide rail. Additional embodiments are contemplated where the guide rail is made of a lubricious material, such as Delrin®. An additional embodiment is contemplated where the guide rail is made of aluminum and the surfaces of the guide rail are anodized, for example to increase surface hardness. In some embodiments, the surfaces of a guide rail and a slidably removable reflective sheet have different hardnesses, for example where the guide rail surface is harder or softer than the slidably removable reflective sheet surface. Use of differing hardnesses is useful, for example, to reduce or eliminate surface galling when a slidably removable reflective sheet is slid in, out or along a guide rail.
For some embodiments, it is not possible to make the guide rails of the present invention as a single extruded structure; for example, it is not possible to fabricate an appropriate extrusion die for a single piece. A solution to this problem is providing a guide rail formed of multiple pieces; any guide rail embodiments described herein can further be fabricated in multiple pieces. The pieces may be joined by adhesive bonding, welding at multiple points, friction, interlocking structures, screws, bolts, or by any combination of these or other attachments methods known to the art. For example,
In order to increase the usable reflective surface area of assemblies comprising guide rails, in an embodiment, the guide rails are adapted to have a longitudinal reflective strip positioned on their upper surface. In a specific embodiment of this aspect, the guide rails comprise a pair of longitudinal tabs for retaining a slidably removable reflective strip.
In an embodiment, a reflective assembly for a solar collector of the present invention comprises multiple slidably removable reflective sheets.
In an embodiment, the reflective solar assemblies of the present invention have an arc shaped cross-section, such that a substantial portion of the incident light is reflected and concentrated to a solar receiver. In a specific embodiment, the cross-section of the reflective solar assemblies is parabolic, as illustrated in
In a specific embodiment, a solar receiver useful with various aspects of the present invention is positioned to absorb light reflected by the slidably removable reflective sheets of a reflective assembly or reflective trough. In a specific embodiment, a solar receiver is positioned along the transverse axis of a reflective solar trough, spanning multiple slidably removable reflective sheets, and positioned at a point of substantially optimal energy capture.
Other embodiments of this aspect include guide rails comprising one or more access points for attaching support struts to the solar receiver. In some embodiments, as in
The reflective assemblies of various embodiments of the present invention may also comprise one or more transverse rail members. Transverse rail members are useful, for example, for increasing the transverse rigidity of slidably removable reflective sheets and/or for the preventing slidably removable reflective sheets from sagging between supporting ribs and/or guide rails. In an embodiment, a transverse rail member is positioned at a longitudinal end of a reflective assembly. In another embodiment, a transverse rail member is positioned in the interior of a reflective assembly. For example,
Useful transverse rail members include many different embodiments for attaching to, supporting, retaining and/or protecting transverse edges of slidably removable reflective sheets. In one embodiment, a transverse rail member comprises a length of angle stock; for example, steel or aluminum angle stock. In another embodiment, a transverse rail member comprises two lengths of angle stock positioned to form a T-shaped or U-shaped member. In another embodiment, a transverse rail member comprises extruded or roll-formed steel or aluminum; for example, steel or aluminum having an L-shaped or other cross-sectional shape known to the art. In another embodiment, a transverse rail member comprises an L-shaped member having one or more notches or cut-out portions for passing over a guide rail and/or supporting rib. In another embodiment, a transverse rail member comprises an angled member having one or more lower support regions for supporting and/or protecting the transverse edges of one or more slidably removable reflective sheets.
In a specific embodiment, a transverse rail member 2013A comprises extruded material having a cross-section as depicted in
In an alternate embodiment shown in
In another aspect, the present invention provides a reflective trough comprising a supporting structure; a plurality of supporting ribs, wherein the plurality of ribs are mounted on the supporting structure; a plurality of guide rails, wherein at least one guide rail is mounted on each of the supporting ribs; and a plurality of slidably removable reflective sheets having longitudinal edges mounted within channels of the guide rails. Supporting structures useful with reflective trough embodiments include, but are not limited to, space frames, torque tube based structures, and other support structures known in the art. U.S. Provisional Patent Applications No. 61/079,382, filed on Jul. 9, 2008, and No. 61/091,095 filed on Aug. 22, 2008, hereby incorporated by reference in their entireties, describe an exemplary support structure and components thereof.
In order to improve the rigidity of the slidably removable reflective sheets, in an embodiment, the slidably removable reflective sheets are optionally placed under tension along a transverse direction. Placing the slidably removable reflective sheets under tension along a transverse direction generally improves the ability of the reflective sheets to withstand other forces, for example forces due to wind or snow loads. In an embodiment, the slidably removable reflective sheets are placed under tension by increasing the transverse spacing of guide rails and/or supporting ribs which the slidably removable reflective sheets are retained by or attached to.
In a specific embodiment, the supporting ribs may comprise multiple portions which are relatively translatable in a transverse direction for applying tension to a slidably removable reflective sheet.
In a specific embodiment, the supporting structure comprises one or more rib translation rails for translating one or more of the supporting ribs in a transverse direction. In an embodiment, a rib translation rail comprises a length of tubing placed over a portion of a support structure for attaching to a supporting rib, such that the supporting rib is translatable along the transverse direction.
In an embodiment, the support structure comprises one or more flexure sections. In another specific embodiment, the support structure comprises one or more compliant features. Rib translation rails, compliant features, and/or flexure sections are useful, for example, for applying tension to one or more slidably removable reflective sheets along a transverse direction or for withstanding transverse dimensional changes due to changes in temperature, gradual changes in seating of the reflective sheets and guide rails over time, and/or other changes. In an exemplary embodiment, the support structure comprises one or more compression springs for applying tension to at least one slidably removable reflective sheet along a transverse direction; the support structure may further comprise one or more bolts or threaded rods which run through the center of each compression spring and allow for the compression of the spring to be adjusted.
U.S. Pat. Nos. 4,372,027, 4,423,719, 4,510,923, 4,596,238, 4,611,575, 4,678,292, 5,058,565, 5,071,243, and 5,964,216.
U.S. Provisional Patent Applications, hereby incorporated by reference in their entireties, No. 61/079,394 filed Jul. 9, 2008; No. 61/079,382 filed Jul. 9, 2008; No. 61/091,095 filed Aug. 22, 2008; and No. 61/144,703 filed Jan. 14, 2009.
Guide rail or Guide rail body
All references throughout this application, for example patent documents including issued or granted patents or equivalents; patent application publications; and non-patent literature documents or other source material; are hereby incorporated by reference herein in their entireties, as though individually incorporated by reference, to the extent each reference is at least partially not inconsistent with the disclosure in this application (for example, a reference that is partially inconsistent is incorporated by reference except for the partially inconsistent portion of the reference) for purposes of enablement and written description.
All patents and publications mentioned in the specification are indicative of the levels of skill of those skilled in the art to which the invention pertains. References cited herein are incorporated by reference herein in their entirety to indicate the state of the art, in some cases as of their filing date, and it is intended that this information can be employed herein, if needed, to exclude (for example, to disclaim) specific embodiments that are in the prior art.
When a group of components is disclosed herein, it is understood that all individual members of those groups and all subgroups are disclosed separately. When a Markush group or other grouping is used herein, all individual members of the group and all combinations and subcombinations possible of the group are intended to be individually included in the disclosure.
Every formulation or combination of components described or exemplified can be used to practice the invention, unless otherwise stated. One of ordinary skill in the art will appreciate that methods, device elements, starting materials, and synthetic methods other than those specifically exemplified can be employed in the practice of the invention without resort to undue experimentation. All art-known functional equivalents, of any such methods, device elements, starting materials, and synthetic methods are intended to be included in this invention. Whenever a range is given in the specification, for example, a temperature range, a time range, or a distance range, all intermediate ranges and subranges, as well as all individual values included in the ranges given are intended to be included in the disclosure.
As used herein, “comprising” is synonymous with “including,” “containing,” or “characterized by,” and is inclusive or open-ended and does not exclude additional, unrecited elements or method steps. As used herein, “consisting of” excludes any element, step, or ingredient not specified in the claim element. As used herein, “consisting essentially of” does not exclude materials or steps that do not materially affect the basic and novel characteristics of the claim. Any recitation herein of the term “comprising”, particularly in a description of components of a composition or in a description of elements of a device, is understood to encompass those compositions and methods consisting essentially of and consisting of the recited components or elements. The invention illustratively described herein suitably may be practiced in the absence of any element or elements, limitation or limitations which is not specifically disclosed herein.
The terms and expressions which have been employed are used as terms of description and not of limitation, and there is no intention in the use of such terms and expressions of excluding any equivalents of the features shown and described or portions thereof, but it is recognized that various modifications are possible within the scope of the invention claimed. Thus, it should be understood that although the present invention has been specifically disclosed by specific and/or preferred embodiments and optional features, modification and variation of the concepts herein disclosed may be resorted to by those skilled in the art, and that such modifications and variations are considered to be within the scope of this invention as defined by the appended claims.
This application is a continuation of U.S. application Ser. No. 12/499,661, filed Jul. 8, 2009, which claims the benefit of U.S. Provisional Patent Application No. 61/079,394, filed on Jul. 9, 2008, both of which are hereby incorporated by reference in their entireties.
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| Number | Date | Country | |
|---|---|---|---|
| 20140055875 A1 | Feb 2014 | US |
| Number | Date | Country | |
|---|---|---|---|
| 61079394 | Jul 2008 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 12499661 | Jul 2009 | US |
| Child | 13914055 | US |
