A solar radiation concentrator may convert received solar radiation (i.e., sunlight) into a concentrated beam and direct the concentrated beam onto a photovoltaic (or, solar) cell. The cell, in turn, may generate electrical current based on photons of the concentrated beam. A concentrator thereby enables a small solar cell to generate electrical current based on photons received over a larger area.
U.S. Patent Application Publication No. 2006/0231133 describes several types of concentrating solar collectors. As generally described therein, solar radiation enters a solid transparent element and strikes reflective material disposed on a convex surface (i.e., a primary mirror) of the element. The radiation is reflected toward reflective material disposed on a smaller and opposite concave surface (i.e., a secondary mirror), and is reflected thereby toward an even smaller area from which a solar cell may receive the radiation. Such operation may allow the concentrator to convert the received solar radiation to electricity using smaller solar cells than would otherwise be required.
The reflective material disposed on the secondary mirror prevents some solar radiation from reaching the primary mirror. The secondary mirror is located near the focus of the primary mirror in order to minimize this shading. However, this location requires the secondary mirror to exhibit a steeply curved aspheric surface and to satisfy precise geometric tolerances with respect to the primary mirror. Formation of such a primary mirror and a secondary mirror on opposite sides of an optically-transparent element (e.g., glass) is difficult and expensive.
Improved solar concentrator designs are desired. Such designs may provide increased power generation per unit area, improved manufacturability, decreased cost, and/or other benefits.
The following description is provided to enable any person in the art to make and use the described embodiments and sets forth the best mode contemplated for carrying out some embodiments. Various modifications, however, will remain readily apparent to those in the art.
Solar cell 110 may comprise a III-V solar cell, a II-VI solar cell, a silicon solar cell, or any other type of solar cell that is or becomes known. Solar cell 110 may comprise any number of active, dielectric and metallization layers, and may be fabricated using any suitable methods that are or become known. Solar cell 110 is capable of generating charge carriers (i.e., holes and electrons) in response to received photons. Although solar cell 110 is shown recessed into core 105, solar cell 110 may be disposed at any suitable position with respect to core 105.
Primary mirror 120 is disposed on convex surface 125 of core 105 and reflective material 130 is disposed on flat surface 140 of core 105 as shown.
Refractive lens 150 is disposed opposite from primary mirror 120. Core 105 and lens 150 may comprise a single molded piece, or lens 150 may be fabricated separately and attached to core 105. Accordingly, lens 150 may comprise a material different from core 105 in some embodiments.
In operation, incoming on-axis (e.g., normal to surface 140) light 160 passes through ambient air and is received at surface 140 and lens 150 of apparatus 100. For clarity,
More specifically, and with respect to the
Dotted lines represent the incoming light 160 received at area B of surface 140. This light 160 passes through core 105 and reflects off of primary mirror 120 as described above. This reflected light also returns to an area at the interface of surface 140 and ambient air, however, the angle at which the light meets the area is less than or equal to arc sin(nair/ncore). Since this light would not experience total internal reflection, reflective material 130 serves to reflect the light toward the active area of solar cell 110.
The reflectivity of a non-total internal reflection (angle of incidence≦arc sin (nair/ncore) may in some instances be greater than that provided by a reflective coating such as material 130. Therefore, the exterior diameter of material 130 may be reduced so that the light received at some small annular zone immediately interior to area A reflects off of the air/surface 140 interface via a non-total internal reflection.
As also shown in
The dimensions of area A, area B, reflective material 130, and lens 150 are subject to the geometry of primary mirror 120 and the refractive index of core 105. In some embodiments, primary mirror 120 is paraboloidial-shaped and the refractive index of core 105 is ˜1.5. Any suitable mirror geometry and core material having any suitable refractive index may be used in some embodiments.
An upper periphery of core 205 of
Primary mirror 220 includes conductive portion 222 and conductive portion 224. Conductive portion 222 defines opening 226 through which concentrated light may exit apparatus 200 and be received by a solar cell. Primary mirror 120 of apparatus 100 may be substituted with primary mirror 220 and/or any other primary mirror illustrated and/or described herein. Alternatively, primary mirror 220 of apparatus 200 may be substituted with primary mirror 120 and/or any other primary mirror illustrated and/or described herein.
Gap 227 is defined between conductive portions 222 and 224 to facilitate electrical isolation thereof. Accordingly, conductive portions 222 and 224 of primary mirror 220 may create a conductive path for electrical current generated by the solar cell. Conductive portions 222 and 224 may also, as described in above-mentioned Application Publication No. 2006/0231133, electrically link photovoltaic cells of adjacent collectors in a concentrating solar collector array.
Apparatus 400 also includes lens 450 disposed at a distance d from surface 440 of core 405. Lens 450 may comprise a material different from core 450 according to some embodiments. Lens 450 may reduce a need for reflective material disposed on surface 440. As will be described below, some embodiments of apparatus 400 include reflective material on surface 440.
According to some embodiments, molding tolerances associated with lens 450 and core 405 provide improved manufacturability and decreased cost.
In operation, incoming light 460 passes through ambient air and is received at surface 440 of apparatus 400.
For some combinations of primary mirror geometries and core indices of refraction, some or all of the incoming on-axis light may be reflected using total internal reflection. For example, primary mirror 420 is not present along a periphery of surface 425 of core 405. Light passing through core 405 and received at this periphery may intercept surface 425 at an angle sufficient to cause total internal reflection of the light toward surface 440. Even if primary mirror 420 was present along the periphery of surface 425, the light incident thereto (if received at a sufficient angle) may be reflected via total internal reflection rather than by primary mirror 420. As total internal reflection exhibits substantially higher reflectivity than alternate reflective materials, the foregoing feature may improve system efficiency.
Lens 450 receives incoming light 465. Lens 450 is shaped to refract light 465 and to direct the light toward surface 440. As shown in
In some embodiments, some incoming normal light may miss lens 465 and intercept surface 440 at an area other than area C. Reflective material may be deposited on appropriate locations of surface 440 to reflect this light toward solar cell 410. This reflective material may be disposed between lens 450 and surface 440 in some embodiments.
An upper periphery of core 505 includes six contiguous facets, but embodiments are not limited thereto. Primary mirror 520 may comprise a contiguous material, may be separated as described with respect to mirror 220, and/or may comprise any suitable configuration.
A position of cover glass 650 may determine a distance d between lenses 550 and cores 505 of array 600. In some embodiments, lenses 550 are mounted such that glass 650 is located between lenses 550 and cores 505.
The present application claims priority to U.S. Provisional Patent Application Ser. No. 61/017,432, filed on Dec. 28, 2007 and entitled “Solid Concentrator With Total Internal Secondary Reflection”, the contents of which are incorporated herein by reference for all purposes.
Number | Date | Country | |
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61017432 | Dec 2007 | US |