請用此 Handle URI 來引用此文件: http://hdl.handle.net/11455/96471
標題: 聚光型太陽能電池聚光精準度檢測與聚光鏡檢測
Concentrating accuracy test of Concentrator Photovoltaic and Concentrating mirror test
作者: 林崇睿
Tsung-Jui Lin
關鍵字: 聚光型太陽能
精準度
鏡片檢測
光學檢測
Concentrator Photovoltaic
Accuracy
Optical test
Optical inspection
引用: [1] A. L. López, V. M. Andreev, 'Concentrator Photovoltaics,' Springer, chap.1, pages 1-24, (2007) [2] M. Yamaguchi, 'III–V compound multi-junction solar cells: present and future,' Solar Energy Materials and Solar Cells, Volume 75, Issues 1–2, Pages 261-269, (2003) [3] A. W. Bett, F. Dimroth, M. Hein, G. Lange, M. Meusel, U. Schubert, G. Siefer, 'Development of III-V-Based Concentrator Solar Cells and Their Application in PV Modules,' Conference Record of the Twenty-Ninth IEEE Photovoltaic Specialists Conference 2002., pages 844-847, (2002) [4] K. Nishioka, T. Takamoto, T. Agui, M. Kaneiwa, Y. Uraoka, T. Fuyuki, 'Annual output estimation of concentrator photovoltaic systems using high-efficiency InGaP/InGaAs/Ge triple-junction solar cells based on experimental solar cell's characteristics and field-test meteorological data,' Solar Energy Materials and Solar Cells, Volume 90, Issue 1, Pages 57-67, 2006 [5] 'Sharp Develops Concentrator Solar Cell with World's Highest Conversion Efficiency of 44.4%,' Sharp Corporation, (2013) [6] Daria F., Roberto R. I., Tahseen J., Firdaus M. S., Carlos G, 'A review of optical concentrators for portable solar photovoltaic systems for developing countries,' Renewable and Sustainable Energy Reviews, Volume 90, Pages 957-968, (2018) [7] Prinsloo G., Dobson R., 'Solar Tracking,' Stellenbosch: solar books, chapter 1, pages 3-32, (2015) [8] T. J. Hebrink, 'Durable Polymeric Films for Increasing the Performance of Concentrators,' Third Generation Photovoltaics, Dr. Vasilis Fthenakis (Ed.), InTech, Chap. 8. pages 183-200, (2012) [9] S. A. Khan, 'Coordinate Geometric Approach to Spherometer,' Bulletin of the IAPT, Vol. 5, No. 6, pages 139-142, (2013) [10] D. H. Lee, '3-Dimensional profile distortion measured by stylus type surface profilometer,' Measurement, Volume 46, Issue 1, Pages 803-814, (2013) [11] J. Hongwei, K. Christopher, W. David, 'Simulation and validation of a prototype swing arm profilometer for measuring extremely large telescope mirror-segments,' Optics Express 18(3), pages 2036-2048, (2010) [12] 廖泰杉, 陳永祥, 許家偉, '影像式光學透鏡模組偏心檢測系統,' 行政院國家科學委員會專題研究計畫成果報告, (2011) [13] 'Principle of the Centering Error Measurement in Reflection and Transmission Mode,' TRIOPTICS, (2014) [14] K. Hibino, D. I. Farrant, B. K. Ward, and B. F. Oreb, 'Dynamic range of Ronchi test with a phase-shifted sinusoidal grating,' Applied Optics, 36(25) pages 6178-6189, (1997) [15] J. D. Upton, 'The Matching Ronchi Test,' The ATM's Workshop, (2001) [16] Jorge C. R., Magdalena M. M., Mariana M. A., Edwin R. H., José Guadalupe S. S., Gilberto S. O., Ramón S. O., Román S. X., José Miguel Z. P., 'Wavefronts, caustics, and ronchigrams of a spherical wave reflected by a spherical mirror,' Optical Society of America A 30(2), pages 177-188, (2013) [17] Z. Zhao, M. Hui, M. Liu, L. Dong, L. Kong, Y. Zhao, 'Centroids computation and point spread function analysis for reverse Hartmann test,' Optics Communications, Volume 387, Pages 328-337, (2017) [18] A. Yamamoto, I. Yamaguchi, 'Surface profilimetry by wavelength scanning Fizeau interferometer,' Optics & Laser Technology, Volume 32, Issue 4, Pages 261-266, (2000) [19] Y. Kim, N. Sugita, M. Mitsuishi, 'Phase-measuring algorithm to suppress inner reflection of transparent parallel plate in wavelength tuning Fizeau interferometer,' Precision Engineering, Volume 48, Pages 67-74, (2017) [20] 'Fizeau Interferometer for Wavefront and Surface Measurement,' TRIOPTICS, (2013) [21] 伍秀菁, 汪若文, 林美吟, '光學元件精密製造與檢測,' 國家實驗研究院儀器科技研究中心, 第十二章, pages 355-386, (2007) [22] P.J. DE GROOT, 'Correlated errors in phase-shifting laser Fizeau interferometry,' Applied optics, 53, pages 4334-4342, (2014)
摘要: 本研究研發聚光型太陽能電池(Concentrator Photovoltaic)聚光光軸校正與聚光能力檢測系統所需之高平行度光源系統,光源之平行度誤差小於0.0046˚,太陽能電池基座與光軸誤差在0.01˚內,檢測範圍為12英吋,聚光型太陽能電池樣品分別為焦點系統與離焦系統,在離焦系統上,改善不對稱的平行光照射在聚光面鏡,使聚光成像更為對稱,判別聚光點更為容易,本研究開發的檢測系統可以清楚判別聚光面鏡的聚光點在晶片上的位置,速率與精度符合線上檢測需求。另外對聚光鏡檢測,檢測範圍為6英吋,適合目前所有聚光型太陽能電池檢測需求,此實驗測試之方形聚光面鏡大小130 × 126 mm,檢測系統可涵蓋大部分主要區域,占總面積93.62 %。最小聚焦直徑約0.8 mm,聚光效果良好,此實驗採用修正後之光學檢測法,可以檢出精度超出干涉法之非接觸式檢測方式,並檢測出塑膠射出製作的聚光面鏡整體特性,其中心範圍45 mm,焦距略長約9.5 mm,依然在光軸中心,此方式可避免將太陽光集中在電池中心,對太陽能電池效率反而有提升,且不影響電池之對準精度。
We have developed a high parallelism light system for optical axis correction and concentrated on the detection system for Concentrator Photovoltaic. The Parallelism light's error is less than 0.0046˚, while both sample base's and optical axis' errors are 0.01˚. All of results are within the detection range of 12 inches. The Concentrator Photovoltaic samples are the focus system and the defocus system respectively. In the defocusing system, we improve the asymmetric parallel light on the concentrating mirror, so the image is more symmetrical, and can be used to distinguish the focusing points. With the detection system, we can clearly distinguish the position of the focal point on the cell. It meets the speed and accuracy of the company requirement. In addition, we check the concentrating mirror. The detection range is 6 inches long, which is suitable for all the detection requirements of Concentrator Photovoltaic at present. The square concentrating mirror size is 130 × 126 mm. Our system can cover most of the main range, which occupies 93.62 % of the total area. The minimum focusing diameter is about 0.8mm, which represents a good focus quality. After deciding on the newly revised method of optical detection, we get a point that using the modified optical test method can detect more accurately than using the method of interference. we can detect the characteristics of the concentrating mirror, which is formed by the injection molding. Its central area is 45mm, and, relatively, its long focal distance is about 9.5mm. Both numbers are still within the center of the optical axis. By adapting the way we use injection molding to make a concentrating mirror, we can avoid the sunlight concentrating on the center of the cell. Thus, the efficiency of solar cells will be improved, and the alignment accuracy of the cells will not be affected.
URI: http://hdl.handle.net/11455/96471
文章公開時間: 10000-01-01
顯示於類別:奈米科學研究所

文件中的檔案:
檔案 大小格式 
nchu-107-7105017004-1.pdf3.98 MBAdobe PDF 請求副本


在 DSpace 系統中的文件,除了特別指名其著作權條款之外,均受到著作權保護,並且保留所有的權利。