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基于吸热管反射成像法测量抛物槽式太阳能聚光器的面形误差 被引量:10

Surface Error of Parabolic Trough Solar Concentrators Based on the Theoretical Overlay Photographic Method
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摘要 为提高抛物槽式太阳能聚光器的聚光效率,需要对聚光器的整体面形进行检测和调整。提出采用吸热管反射成像法检测槽式聚光器各子镜的安装位置及倾斜角度,进而获得聚光器的整体面形信息。通过测量相机与被测聚光器的相对位置,可计算吸热管在待检测子镜中的成像位置及形状,并推导了吸热管在聚光器中的理论成像位置计算公式。进行了吸热管反射成像法检测槽式聚光器面形的实验。通过调整聚光器子镜的安装位置和倾斜角度,使吸热管在子镜中的实际成像位置与理论位置重合,验证了检测方法的正确性和可行性。 To improve the concentrate efficiency of the parabolic trough concentrator, the measurement and adjustment of overall surface are needed. The theoretical overlay photographic method is used to measure the installation position and tilt angle of facet mirrors, and then the concentrator surface information is obtained. It can calculate the theoretical shape and position of the receiver in image by measuring the relative position of concentrator and cameras, while the theory position formula of receiver is deduced in concentrator. The experiment of the theoretical overlay photographic method measuring the concentrator surface is done. This method can match the actual position of receiver to theoretical position in image by adjusting installation position of facet mirrors, which verifies the feasibility and correctness of this method.
作者 任兰旭 魏秀东 牛文达 肖君 卢振武
机构地区 中国科学院长春光学精密机械与物理研究所 中国科学院大学
出处 《光学学报》 EI CAS CSCD 北大核心 2014年第4期105-110,共6页 Acta Optica Sinica
基金 国家973计划(2010CB227101) 国家863计划(2012AA050602) 国家自然基金(11174275)
关键词 光学器件 聚光效率 聚光器面形 吸热管反射成像法 抛物槽式聚光器 optical devices concentrate efficiency concentrator surface theoretical overlay photographic method parabolic trough concentrator
分类号 O439 [机械工程—光学工程]
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参考文献13

  • 1D Kearney, H Price. Recent Advances in Parabolic Trough Solar Power Plant Technology [M]. Colorado: National Renewable Energy Laboratory Golden Co, 2005.
  • 2Gong Guanjie, Huang Xinyan, Wang Jun, et al.. An optimized model and test of the China′s first high temperature parabolic trough solar receiver [J]. Solar Energy, 2010, 84(12): 2230-2245.
  • 3Liu Qibin, Yang Minlin, Lei Jing, et al.. Modeling and optimizing parabolic trough solar collector systems using the least squares support vector machine method [J]. Solar Energy, 2012, 86(7): 1973-1980.
  • 4S A Jones, D R Neal, J K Gruetzner, et al.. VSHOT: a tool for characterizing large, imprecise reflectors [C]. Conference on Space Processing of Materials, 1996, CONF-960848-29.
  • 5T Wendelin. Parabolic trough optical characterization at the national renewable energy laboratory [C]. Proceedings of the DOE Solar Energy Technologies Program Review Meeting, 2004: 2005-2067.
  • 6B L Butler, R B Pettit. Optical evaluation techniques for reflecting solar concentrators [C]. SPIE, 1977, 144: 43-49.
  • 7E Lupfurt, K Pottler, S Ulmer, et al.. Parabolic trough analysis and enhancement techniques [C]. International Solar Energy Conference, 2005.
  • 8M R Shortis, G Johnston. Photogrammetry: an available surface characterization tool for solar concentrators, part 2: assessment of surfaces [J]. Journal of Solar Energy Engineering, 1997, 119(4): 281-291.
  • 9K Pottler, E Lupfert, G H G Johnston, et al.. Photogrammetry: a powerful tool for geometric analysis of solar concentrators and their components [J]. ASME Journal of Solar Energy Engineering, 2005, 127(1): 94-101.
  • 10T A Moss, D A Brosseau. Final test result of a Schott HCE on a LS-2 collector [C]. International Solar Energy Conference, 2005, 6-12.

同被引文献113

  • 1高栋,孔令豹,姚英学,杜雪.光学自由曲面面形误差评定算法的研究[J].哈尔滨工业大学学报,2006,38(10):1630-1632. 被引量:6
  • 2王军,张耀明,金保升,刘德有,安翠翠.太阳能热发电系列文章(15)——太阳能热发电中的聚光器[J].太阳能,2007(9):30-34. 被引量:8
  • 3Rafael Illanes, Adolfo De Francisco, Francisco Nunez, et al. Dynamic simulation and modelling of stand-alone PV systems by using state equations and numerical integration methods[J]. Applied Energy, 2014, 135(15): 440-449.
  • 4Peter Kovacik, Hazele Assender, Andrew A R Watt, et al. Morphology control in co-evaporated bulk heterojunction solar cells[J]. Solar Energy Materials & Solar Cells, 2013, 117: 22-28.
  • 5Zhao Lijuan, Hu Linfeng. Synthesis and applications of CdSE nano-tetrapods in hybrid photovoltaic devices[J]. Pure and Applied Chemistry, 2012, 84(12): 2549-2558.
  • 6Liu Guodong, Ji Shulin, Xu Guoping, et al. Interface engineering: boosting the energy conversion efficiencies for nanostructured solar cells[J]. Pure and Applied Chemistry, 2012, 84(12): 2653-2675.
  • 7Zhao Yuning, Fay Patrick, Wibowo Andre, et al. Via-hole fabrication for III-V triple-junction solar cells[J]. Journal of Vacuum Science and Technology B, 2012, 30(6): 06F401.
  • 8Yong Sin Kim, Sung Mo Kang, Roland Winston. Tracking control of high-concentration photovoltaic systems for minimizing power losses[J]. Progress in Photovoltaics, 2014, 22(9): 1001-1009.
  • 9Yuan Hsiang Zou, Tian Shiang Yang. Optical performance analysis of a HCPV solar concentrator yielding highly uniform cell irradiance[J]. Solar Energy, 2014, 107(9): 1-11.
  • 10F Almonacid, P J Perez-Higueras, Eduaido F Fernandez, et al. Relation between the cell temperature of a HCPV module and atmospheric parameters[J]. Solar Energy Materials and Solar Cells, 2012, 105: 322-327.

引证文献10

二级引证文献37

光学学报
2014年 第4期

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