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Airborne shape measurement of parabolic trough collector fields

Prahl, Christoph ; Stanicki, Badrudin ; Hilgert, Christoph ; [et al.]

Elsevier BV ; 2013

In: Solar Energy Vol. 91 ( 2013-05), p. 68-78

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In: Solar Energy, Elsevier BV, Vol. 91 ( 2013-05), p. 68-78

Type of Medium: Online Resource

ISSN: 0038-092X

URL: Article

DOI: 10.1016/j.solener.2013.01.012

Language: English

Publisher: Elsevier BV

Publication Date: 2013

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Heliostat Shape and Orientation by Edge Detection

Röger, Marc ; Prahl, Christoph ; Ulmer, Steffen

ASME International ; 2010

In: Journal of Solar Energy Engineering Vol. 132, No. 2 ( 2010-05-01)

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In: Journal of Solar Energy Engineering, ASME International, Vol. 132, No. 2 ( 2010-05-01)

Abstract: The heliostats of central receiver solar power plants reach dimensions up to 150 m2 with focal lengths up to 1000 m. Their optical properties and tracking accuracy have great influence on the power plant efficiency and need to be monitored both at plant start up and during operation. Up to now, there are few efficient and fast measurement techniques that allow the heliostat properties to be measured. Flux density measurements and close-range photogrammetry are possible approaches, yet they do not fulfill the requirement to be accurate, inexpensive, and fast at the same time. In this paper, we present a noncontact measurement principle, which uses edge detection to extract the heliostat and facet vertices. This information is used to calculate the surface normals. Furthermore, the corners can replace retroreflective targets generally used in close-range photogrammetry, thus, enabling a fast and completely automatic evaluation of the three-dimensional heliostat structure. The pictures are provided by a digital camera, which is mounted on a pan tilt head on top of the central receiver tower, offering visibility to all heliostats and allowing the automated qualification of whole heliostat fields in a short period of time. It is shown that measurement uncertainties in heliostat orientation for the investigated heliostat are below 4 mrad in 80% of the relevant heliostat positions. Heliostat orientation is available within three minutes. Photogrammetric measurements based on edge detection at a 40 m2 CESA-1 heliostat at the Plataforma Solar de Almerìa exhibit an accuracy of 1.6 mrad for a single-facet normal vector with the results being available within 30 min. The reduced measurement time allows the economic characterization of entire heliostat fields. The lower accuracy compared with manual photogrammetry with retroreflective targets is still sufficient to detect facet misalignments in existing heliostat fields.

Type of Medium: Online Resource

ISSN: 0199-6231 , 1528-8986

URL: Article

DOI: 10.1115/1.4001400

Language: English

Publisher: ASME International

Publication Date: 2010

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Techniques to Measure Solar Flux Density Distribution on Large-Scale Receivers

Röger, Marc ; Herrmann, Patrik ; Ulmer, Steffen ; [et al.]

ASME International ; 2014

In: Journal of Solar Energy Engineering Vol. 136, No. 3 ( 2014-08-01)

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In: Journal of Solar Energy Engineering, ASME International, Vol. 136, No. 3 ( 2014-08-01)

Abstract: Flux density measurement applied to central receiver systems delivers the spatial distribution of the concentrated solar radiation on the receiver aperture, measures receiver input power, and monitors and might control heliostat aimpoints. Commercial solar tower plants have much larger aperture surfaces than the receiver prototypes tested in earlier research and development (R & D) projects. Existing methods to measure the solar flux density in the receiver aperture face new challenges regarding the receiver size. Also, the requirements regarding costs, accuracy, spatial resolution, and measuring speed are different. This paper summarizes existent concepts, presents recent research results for techniques that can be applied to large-scale receivers and assesses them against a catalog of requirements. Direct and indirect moving bar techniques offer high measurement accuracy, but also have the disadvantage of large moving parts on a solar tower. In the case of external receivers, measuring directly on receiver surfaces avoids moving parts and allows continuous measurement but may be not as precise. This promising technique requires proper scientific evaluation due to specific reflectance properties of current receiver materials. Measurement-supported simulation techniques can also be applied to cavity receivers without installing moving parts. They have reasonable uncertainties under ideal conditions and require comparatively low effort.

Type of Medium: Online Resource

ISSN: 0199-6231 , 1528-8986

URL: Article

DOI: 10.1115/1.4027261

Language: English

Publisher: ASME International

Publication Date: 2014

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