&lt;title&gt;Optical Evaluation Techniques For Reflecting Solar Concentrators&lt;/title&gt;

“…良好的聚光反射镜光学误差较小，能将更多能量聚焦到接收器上 (Ulmer, Heinz et al 2009)。为了减小聚光反射镜光学误差，改进聚光反射镜质量，人们发展了多种方法来测量这种误差 (Wendelin and Grossman 1994;Shortis and Johnston 1996;Arqueros, Jimenez et al 2003;Ulmer, Heinz et al 2009)。反射镜光学误差的主要方面是光学表面的形状误差，可以分成两种误差，一种是入射位置不同于理论位置，另一种是表面坡度与理论值不同 (Winston, Miñano et al 2005)。从光学角度来看，通常的观点认为位置误差不重要，只需要考虑坡度误差 (Rabl 1985)。坡度误差是反射镜表面倾斜角度与理想镜面的差别 (Ulmer, Heinz et al 2009)，一般将这种倾斜角度误差分解成相互垂直的两个方向上的分量，分别用 dw x and dw y 来表示，其方向的选取，与镜面加工工艺相关产生的偏差分布有关，可以通过光学测量获得。根据反射定理，入射光经理想镜面反射后，反射光与法线之间夹角等于入射光与法线之间的夹角，而且入射线，反射线和法线在同一个平面内。在实际镜面上，由于存在倾斜偏差，反射点的法线方向因倾斜方向改变而改变了，反射方向也就改变了。通常镜面各反射点的法线方向的改变是随机的，反射光线的角度分布也是随机，使用分布函数来描述。现有实验数据表明，镜面误差和反射光线的误差分布可用标准椭圆高斯分布描述 (Butler and Pettit 1977;Bendt and Rabl 1981…”

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Theoretical analysis of error transfer from the surface slope to the reflected ray and their application in the solar concentrated collector

Huang¹,

Han²

2012

Solar Energy

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“…In contrast to measurement tools for monitoring solar flux in the focal region [4,5], the photogrammetric method directly delivers coordinates of selected test points and thus allows performance assessments of the concentrator to be made. Whereas other surface evaluation methods are limited to special shapes, e. g. to point focusing devices [6] (such as the (V)SHOT-method [7,8] or the SCCANmethod [9]), or to linear parabolic concentrators (indoor [10,11] or outdoor laser ray trace [12]), photogrammetry is a universal method for testing almost any type of concentrator or structure. …”

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confidence: 99%

Photogrammetry: A Powerful Tool for Geometric Analysis of Solar Concentrators and Their Components

Pottler¹,

̈pfert²,

Johnston

et al. 2004

Solar Energy

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Digital close range photogrammetry has proven to be a precise and efficient measurement technique for the assessment of shape accuracies of solar concentrators and their components. The combination of high quality mega-pixel digital still cameras, appropriate software and calibrated reference scales in general is sufficient to provide coordinate measurements with precisions of 1:50,000 or better. The extreme flexibility of photogrammetry to provide high accuracy 3-D coordinate measurements over almost any scale makes it particularly appropriate for the measurement of solar concentrator systems. It can also provide information for the analysis of curved shapes and surfaces, which can be very difficult to achieve with conventional measurement instruments. The paper gives an overview of quality indicators for photogrammetric networks, which have to be considered during the data evaluation to augment the measurement precision. A selection of measurements done on whole solar concentrators and their components are presented. The potential of photogrammetry is demonstrated by presenting measured effects arising from thermal expansion and gravitational forces on selected components. The measured surface data can be used to calculate slope errors and undertake raytrace studies to compute intercept factors and assess concentrator qualities.Keywords: Photogrammetry, Quality Control, Concentrator Analysis, Parabolic Trough Collector, Ray-Tracing INTRODUCTIONThe optical performance of solar concentrating collectors is very sensitive to inaccuracies of components and assembly. Because of a finite sun-shape and extant imprecisions of the collector system (e.g. tracking, receiver alignment, mirror alignment, mirror shape and mirror specularity) the interception of light at the focal receiver is reduced. High precision photogrammetry is an appropriate tool to measure 3D-coordinates of concentrator support points and mirror surfaces, especially for the analysis of large concentrators [1,2,3]. In contrast to measurement tools for monitoring solar flux in the focal region [4,5], the photogrammetric method directly delivers coordinates of selected test points and thus allows performance assessments of the concentrator to be made. Whereas other surface evaluation methods are limited to special shapes, e. g. to point focusing devices [6] (such as the (V)SHOT-method [7,8] or the SCCANmethod [9]), or to linear parabolic concentrators (indoor [10,11] or outdoor laser ray trace [12]), photogrammetry is a universal method for testing almost any type of concentrator or structure.

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<title>Optical Evaluation Techniques For Reflecting Solar Concentrators</title>

Cited by 14 publications

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Prediction and optimization of the performance of parabolic solar dish concentrator with sphere receiver using analytical function

Prediction and optimization of the performance of parabolic solar dish concentrator with sphere receiver using analytical function

Theoretical analysis of error transfer from the surface slope to the reflected ray and their application in the solar concentrated collector

Photogrammetry: A Powerful Tool for Geometric Analysis of Solar Concentrators and Their Components

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