Systems, methods, and apparatus by which solar energy may be collected to provide electricity, heat, or a combination of heat and electricity are disclosed herein.
대표청구항▼
1. A concentrating solar energy collector comprising: a linearly elongated reflector having a linear focus;a linearly elongated receiver oriented parallel to and located at or approximately at the linear focus of the reflector and fixed in position with respect to the reflector; anda support structu
1. A concentrating solar energy collector comprising: a linearly elongated reflector having a linear focus;a linearly elongated receiver oriented parallel to and located at or approximately at the linear focus of the reflector and fixed in position with respect to the reflector; anda support structure supporting the reflector and the receiver and pivotally mounted to accommodate rotation of the support structure, the reflector, and the receiver about a rotation axis parallel to the linear focus of the reflector;wherein the reflector comprises a plurality of linearly elongated reflective elements each having a long axis, and the linearly elongated reflective elements are arranged on and attached to a sheet of metal in two or more parallel side-by-side rows with the long axes of the linearly elongated reflective elements and the rows oriented parallel to the linear focus of the reflector, the sheet of metal providing longitudinal support parallel to the rotation axis along the length of the linearly elongated reflective elements;wherein the reflector has a reflective surface that is or approximates a portion of a parabolic surface, with the reflector located primarily or entirely on one side of a symmetry plane of the parabolic surface; andwherein the support to which the sheet of metal is attached, the transverse reflector supports structure comprises a plurality of transverse reflector supports supporting the reflector and extending transverse to the rotation axis and a corresponding plurality of receiver supports each connected to and extending from only one outer end of its corresponding transverse reflector support to support the receiver above the reflector, with the receiver supports located along an edge of the reflector adjacent the symmetry plane of the parabolic surface. 2. The concentrating solar energy collector of claim 1, wherein the receiver comprises solar cells that, in operation of the solar energy collector, are illuminated by solar radiation concentrated by the reflector onto the receiver. 3. The concentrating solar energy collector of claim 1 wherein the receiver comprises one or more coolant channels through which, in operation of the solar energy collector, fluid may pass to collect heat from solar radiation concentrated by the reflector onto the receiver. 4. The concentrating solar energy collector of claim 2, wherein the receiver comprises one or more coolant channels through which, in operation of the solar energy collector, fluid may pass to collect heat from solar radiation concentrated by the reflector onto the receiver. 5. The concentrating solar energy collector of claim 1, wherein the rotation axis is oriented in an East-West or an approximately East-West direction. 6. The concentrating solar energy collector of claim 1, wherein surfaces of the transverse reflector supports orient the sheet of metal, and thus the linearly elongated reflective elements attached to it, in a desired orientation with respect to the receiver. 7. The concentrating solar energy collector of claim 1 wherein: the receiver comprises upper and lower surfaces on opposite sides of the receiver, the lower surface of the receiver located at or approximately at the linear focus of the reflector, the upper surface of the receiver comprising solar cells arranged to face the sun and thereby be directly illuminated by solar radiation, and not receive solar radiation concentrated by the reflector, when the reflector is oriented to concentrate solar radiation on the lower surface of the receiver;the solar energy collector comprises a drive system powered by the solar cells on the upper surface of the receiver and coupled to the support structure to rotate the support structure, the reflector, and the receiver about the rotation axis; andthe solar cells of the upper surface of the receiver generate sufficient electricity under a solar irradiance of at least about 100 Watts per square meter of solar cell to operate the drive system. 8. The concentrating solar energy collector of claim 7 wherein the receiver comprises one or more coolant channels through which fluid may pass to collect heat from solar radiation concentrated by the reflector onto the receiver. 9. The concentrating solar energy collector of claim 8 comprising a pump that pumps the fluid through the one or more coolant channels, wherein the pump is powered by the solar cells of the upper surface of the receiver. 10. The solar energy collector of claim 8, comprising a pump that pumps the fluid through the one or more coolant channels, wherein the pump is powered by an energy source external to the solar energy collector. 11. The concentrating solar energy collector of claim 8, wherein the lower surface of the receiver comprises solar cells that, in operation of the solar energy collector, are illuminated by solar radiation concentrated by the reflector onto the receiver. 12. The concentrating solar energy collector of claim 1 comprising: a first solar radiation sensor that, when illuminated by solar radiation concentrated by the reflector, generates a signal by which rotation of the support structure, the reflector, and the receiver may be controlled to maximize concentration of solar radiation onto the receiver. 13. The concentrating solar energy collector of claim 12, wherein the first solar radiation sensor is located in a focal region of the reflector. 14. The concentrating solar energy collector of claim 13, wherein the first solar radiation sensor comprises two solar radiation detectors positioned on opposite sides of a center line of the linear focus of the reflector. 15. The concentrating solar energy collector of claim 14, wherein each solar radiation detector is linearly elongated in a direction transverse to the linear focus of the reflector. 16. The concentrating solar energy collector of claim 12, comprising a second solar radiation sensor positioned to be illuminated directly by solar radiation not concentrated by the reflector, the second solar radiation sensor generating a signal by which rotation of the support structure, the reflector, and the receiver may be controlled to illuminate the first solar radiation sensor with solar radiation concentrated by the reflector. 17. The concentrating solar energy collector of claim 16, wherein the second solar radiation sensor is fixed in position with respect to reflector and the receiver and located in a plane oriented perpendicular to an optical axis of the reflector. 18. The concentrating solar energy collector of claim 17, wherein the second solar radiation sensor comprises a linearly elongated gnomon and two linearly elongated solar radiation detectors positioned on opposite sides of the gnomon, wherein the long axes of the gnomon and the linearly elongated solar radiation detectors are arranged parallel to the linear focus of the reflector. 19. The concentrating solar energy collector of claim 18, wherein the first solar radiation sensor is located in a focal region of the reflector and comprise two solar radiation detectors positioned on opposite sides of a center line of the linear focus of the reflector.
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이 특허에 인용된 특허 (60)
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