Rotating shadowband irradiometers (RSIs) are a common type of radiation sensors for measurement of direct normal irradiance (DNI) at remote sites where daily maintenance of the instruments is not feasible or practicable. Their primordial lower accuracy due to systematic deviations of the photodiode response can be improved significantly with a thorough calibration of each RSI against high precision sensors and application of suitable corrections on the raw data. With different available correction functions for the systematic errors, RSI data coincide with first class reference sensors within 2–3% root mean square deviation (RMSD) for 10 min averages of DNI and meet the annual irradiation sum within 1.5%. Such comparisons of RSI data to reference irradiances have only been published for a small number of sites. To endorse the credibility of RSI measurements, it has to be shown that these accuracies derived for certain locations are also valid at other sites with differing atmospheric conditions. Therefore, a parallel measurement campaign with six RSIs and a reference station with first class and secondary standard instrumentation has been performed in the in the extreme climate of the United Arab Emirates (UAE). The results of this comparison are presented in this paper. The stated empiric accuracy could be validated and confirmed for the UAE.
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October 2016
Research-Article
Validation of Direct Beam Irradiance Measurements From Rotating Shadowband Irradiometers in a Region With Different Atmospheric Conditions
Norbert Geuder,
Norbert Geuder
Faculty of Civil Engineering, Building Physics,
and Business Management,
Hochschule für Technik Stuttgart,
Schellingstr. 24,
Stuttgart 70174, Germany
e-mail: norbert.geuder@hft-stuttgart.de
and Business Management,
Hochschule für Technik Stuttgart,
Schellingstr. 24,
Stuttgart 70174, Germany
e-mail: norbert.geuder@hft-stuttgart.de
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Olaf Goebel,
Olaf Goebel
Department Hamm 1, Energy Technology,
Hochschule Hamm-Lippstadt,
Marker Allee 76-78,
Hamm 59063, Germany
e-mail: olaf.goebel@hshl.de
Hochschule Hamm-Lippstadt,
Marker Allee 76-78,
Hamm 59063, Germany
e-mail: olaf.goebel@hshl.de
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Stefan Wilbert,
Stefan Wilbert
German Aerospace Center (DLR),
Institute of Solar Research,
Plataforma Solar de Almería,
Ctra. de Senés s/n km 4,
Apartado 39,
Almería 04001, Spain
e-mail: stefan.wilbert@dlr.de
Institute of Solar Research,
Plataforma Solar de Almería,
Ctra. de Senés s/n km 4,
Apartado 39,
Almería 04001, Spain
e-mail: stefan.wilbert@dlr.de
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Benedikt Pulvermueller
Benedikt Pulvermueller
SolarMillennium AG,
Nägelsbachstr. 33,
Erlangen 91052, Germany
e-mail: pulvermueller@solar-millennium.de
Nägelsbachstr. 33,
Erlangen 91052, Germany
e-mail: pulvermueller@solar-millennium.de
Search for other works by this author on:
Norbert Geuder
Faculty of Civil Engineering, Building Physics,
and Business Management,
Hochschule für Technik Stuttgart,
Schellingstr. 24,
Stuttgart 70174, Germany
e-mail: norbert.geuder@hft-stuttgart.de
and Business Management,
Hochschule für Technik Stuttgart,
Schellingstr. 24,
Stuttgart 70174, Germany
e-mail: norbert.geuder@hft-stuttgart.de
Roman Affolter
Olaf Goebel
Department Hamm 1, Energy Technology,
Hochschule Hamm-Lippstadt,
Marker Allee 76-78,
Hamm 59063, Germany
e-mail: olaf.goebel@hshl.de
Hochschule Hamm-Lippstadt,
Marker Allee 76-78,
Hamm 59063, Germany
e-mail: olaf.goebel@hshl.de
Basel Dahleh
Mohamed Al Khawaja
Stefan Wilbert
German Aerospace Center (DLR),
Institute of Solar Research,
Plataforma Solar de Almería,
Ctra. de Senés s/n km 4,
Apartado 39,
Almería 04001, Spain
e-mail: stefan.wilbert@dlr.de
Institute of Solar Research,
Plataforma Solar de Almería,
Ctra. de Senés s/n km 4,
Apartado 39,
Almería 04001, Spain
e-mail: stefan.wilbert@dlr.de
Benedikt Pape
Benedikt Pulvermueller
SolarMillennium AG,
Nägelsbachstr. 33,
Erlangen 91052, Germany
e-mail: pulvermueller@solar-millennium.de
Nägelsbachstr. 33,
Erlangen 91052, Germany
e-mail: pulvermueller@solar-millennium.de
1Corresponding author.
Contributed by the Solar Energy Division of ASME for publication in the JOURNAL OF SOLAR ENERGY ENGINEERING: INCLUDING WIND ENERGY AND BUILDING ENERGY CONSERVATION. Manuscript received February 16, 2011; final manuscript received October 19, 2015; published online July 28, 2016. Assoc. Editor: Philippe Blanc.
J. Sol. Energy Eng. Oct 2016, 138(5): 051007 (8 pages)
Published Online: July 28, 2016
Article history
Received:
February 16, 2011
Revised:
October 19, 2015
Citation
Geuder, N., Affolter, R., Goebel, O., Dahleh, B., Al Khawaja, M., Wilbert, S., Pape, B., and Pulvermueller, B. (July 28, 2016). "Validation of Direct Beam Irradiance Measurements From Rotating Shadowband Irradiometers in a Region With Different Atmospheric Conditions." ASME. J. Sol. Energy Eng. October 2016; 138(5): 051007. https://doi.org/10.1115/1.4034070
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