Performance characteristics of a perforated shadow band in the presence of cloud

•The performance of a perforated shadow band is described under cloudy conditions.•Global and diffuse irradiance can be measured with a single pyranometer.•Adaptive interpolation is shown to lower uncertainty when filling data gaps.•RMSD and MBD are higher in the mid-clearness index range. The perfo...

Full description

Saved in:
Bibliographic Details
Published in:Solar energy 2016-12, Vol.139, p.533-546
Main Authors: Brooks, Michael J., von Backström, Theodor W., van Dyk, E. Ernest
Format: Article
Language:English
Subjects:
Cloudy conditions
Decomposition
Diffuse irradiance
Global irradiance
Missing data
Perforated shadow band
Solar energy
Time series
Uncertainty
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•The performance of a perforated shadow band is described under cloudy conditions.•Global and diffuse irradiance can be measured with a single pyranometer.•Adaptive interpolation is shown to lower uncertainty when filling data gaps.•RMSD and MBD are higher in the mid-clearness index range. The perforated shadow band enables the decomposition of global horizontal solar irradiance (GHI) so as to obtain diffuse horizontal and direct normal irradiance components (DHI and DNI). As a single-pyranometer system, it offers a low-cost alternative to dual-sensor radiometric schemes, but a comprehensive performance analysis has only been conducted under clear sky conditions. This study addresses perforated band (PB) behavior in the presence of cloud when the resulting radiometric trace exhibits stochasticity and a sensor exposure model is required to separate resulting fragmented GHI and DHI components prior to reconstitution as continuous time-series. Various interpolation techniques are tested for replacing patches of missing data caused by the band’s operation with the aim of minimizing root mean square difference (RMSD) relative to reference data. Given the effect of cloud on performance, uncertainties are reported as a function of daily clearness index, rather than as constants. For GHI, the RMSD uncertainties range between 6% for high clearness indices and around 36% for values between 0.3 and 0.4. Bias is typically negative, and the PB system underestimates GHI by between 1% (clearer skies) and 7% (partly cloudy skies). It is found that deploying interpolation schemes adaptively in response to the prevailing clearness index effectively reconstitutes fragmented GHI curves when cloud is present, while decomposition models assist in replacing missing DHI data under heavily cloudy and overcast conditions. Root mean square differences of around 20% can be expected for DHI measurements with mean bias varying between −5% for overcast conditions and +8% for clearer skies. The DNI results are obtained by calculation from DHI and GHI values, with RMSD peaking at about 200W/m2 in the mid-clearness index range, reducing to 30W/m2 under mainly overcast conditions and to 90W/m2 for high clearness index values. The results of the study also offer insight to the more general problem of replacing missing data in radiometric time series.
ISSN:0038-092X
1471-1257
DOI:10.1016/j.solener.2016.10.019