Calibration system for solar collector installation
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01J-001/20
F24J-002/38
H01L-031/0525
F24J-002/10
F24J-002/12
F24J-002/18
H01L-031/052
H01L-031/042
출원번호
US-0897268
(2013-05-17)
등록번호
US-8937270
(2015-01-20)
발명자
/ 주소
Fangman, Michael E.
출원인 / 주소
CEWA Technologies, Inc.
대리인 / 주소
Dickinson Wright PLLC
인용정보
피인용 횟수 :
0인용 특허 :
16
초록▼
A solar concentrator calibration tool that compensates for inconsistencies in the fabrication, assembly and installation of a solar collector system, permitting the solar collector to perform optimally. The calibration tool provides feedback information to a supervisory control processor, allowing t
A solar concentrator calibration tool that compensates for inconsistencies in the fabrication, assembly and installation of a solar collector system, permitting the solar collector to perform optimally. The calibration tool provides feedback information to a supervisory control processor, allowing the processor to compare the expected position of the sun to the “actual” position found by the calibration tool. The processor then generates a calibration signal, thereafter used by the collector's movement control mechanism, to compensate the tracking of the solar collector to accurately follow the movement of the sun, unconstrained by the effects of the construction inconsistencies.
대표청구항▼
1. A solar collector alignment calibration tool, comprising: an alignment element that generates an alignment signal for a solar collector to maintain an optical axis of the solar collector aligned to a maximum radiation position of a sun, wherein the alignment element comprises a solar sensing arra
1. A solar collector alignment calibration tool, comprising: an alignment element that generates an alignment signal for a solar collector to maintain an optical axis of the solar collector aligned to a maximum radiation position of a sun, wherein the alignment element comprises a solar sensing array that senses radiation from the sun, and wherein the alignment element is positioned along the optical axis;a position encoder that generates elevation and azimuth data of the solar collector including upon alignment of the optical axis with the maximum radiation position;a computer-readable storage medium having encoded thereon machine instructions for computing a location difference value; anda processing element that executes the program of instructions to: read a current expected position of the sun,read current elevation and azimuth data of the solar collector generated by the position encoder, andcompute the location difference value based on the current expected position of the sun and the current elevation and azimuth data. 2. The calibration tool of claim 1, wherein the alignment element generates the alignment signal and the position encoder generates the elevation and azimuth data following a movement tracking of the sun during an alignment calibration process over a predetermined period, and wherein the location difference value is a function of location difference values computed by the processing element during the alignment calibration process over the predetermined period. 3. The calibration tool of claim 2, wherein, following the alignment calibration process, the processing element operates to provide the location difference value to a processor of the solar collector, wherein the processor applies the location difference value as an offset signal to correct between the expected position of the sun and an actual position of the solar collector. 4. The calibration tool of claim 3, wherein the alignment element is removably affixed to the solar collector. 5. The calibration tool of claim 4, wherein the alignment element is removed from the solar collector following the alignment calibration process. 6. The calibration tool of claim 1, wherein the solar collector is in a fixed location relative to Earth. 7. The calibration tool of claim 6, where in the fixed location is a fixed geographic location on Earth. 8. The calibration tool of claim 1, wherein the processing element further operates to generate an adjustment signal to adjust the position of the solar collector based on the location difference value to maintain the optical axis of the solar collector aligned to the maximum radiation position of the sun. 9. The calibration tool of claim 8, wherein the processing element further operates to provide the position adjustments to a motor control module of the solar collector. 10. The calibration tool of claim 1, wherein the expected position of the sun comprises sun movement data based on a latitude and longitude of the solar collector. 11. A calibration tool for aligning an optical axis of a solar collector with a solar emitter during an alignment calibration process, comprising: an alignment element that generates an alignment signal usable to drive the solar collector such that the optical axis is aligned with an observed position of the solar emitter to maximize solar radiation reception from the solar emitter, wherein the alignment element comprises a solar sensing array that senses the solar radiation from the solar emitter, and wherein the alignment element is positioned along the optical axis;a position encoder that provides a position of the solar collector when the optical axis is aligned with the observed position of the solar emitter; anda processor that: compares the position of the solar collector when the optical axis is aligned with the observed position of the solar emitter to an expected position of the solar collector defined as a positioned that maximizes collection of solar radiation based on an expected track of the solar emitter, andgenerates a difference value useable to maintain the optical axis of the solar collector in alignment with the solar emitter after execution of the alignment calibration process. 12. The calibration tool of claim 11, wherein the processor: applies the alignment signal to a solar collector positioning device to drive the optical axis of the solar collector into alignment with the observed position of the solar emitter. 13. A solar collector alignment system, comprising: an alignment element comprising a solar sensor array positioned along an optical axis of a solar collector that senses solar radiation from a solar emitter and a position difference between a current position of the optical axis of the solar collector and an optimum position of the solar collector defined as a position of the solar collector having maximum solar radiation incidence;a computer-readable storage medium having stored thereon a program of instructions for aligning a solar collector with the solar emitter; anda processor when executing the program of instructions: receives the optimum position,receives an expected position of the solar collector defined as an expected position of the solar emitter,computes a difference value defined as a difference between the optimum position and the expected position, andstores the difference value as an offset to apply to a solar collector positioning signal to provide optimum tracking of movement of the solar emitter by the solar collector. 14. The system of claim 13, further comprising a position element that generates optimum elevation and azimuth data of the solar collector including when the optical axis aligns with the maximum radiation position, wherein the optimum elevation and azimuth comprise the optimum position. 15. The system of claim 14, further comprising an alignment mechanism that drives the optical axis of the solar collector to align with the optimum position. 16. A solar collector alignment system, comprising: an alignment element comprising a solar sensor array positioned along an optical axis of a solar collector, the solar sensor array sensing solar radiation from a solar emitter and a current position of the optical axis of the solar collector when in optimal alignment with the solar emitter, the optimal alignment defined as a position of the solar collector having maximum solar radiation incidence;a computer-readable storage medium having stored thereon a program of instructions for aligning the solar collector with the solar emitter; anda processor that, when executing the program of instructions: receives the optimum alignment position,receives an expected position of the solar collector defined as an expected position of the solar emitter with the optical axis of the solar collector aligned with the solar emitter such that the solar collector receives the maximum radiation incidence,computes a difference value defined as a difference between the optimum position and the expected position, andstores the difference value as an offset to apply to a solar collector positioning signal to provide optimum tracking of movement of the solar emitter by the solar collector.
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이 특허에 인용된 특허 (16)
Rabinowitz,Mario, Advanced micro-optics solar energy collection system.
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