Measurement of diffuse and plane of array irradiance by a combination of a pyranometer and an all-sky imager

Niklas Benedikt Blum,Stefan Wilbert,Bijan Nouri,Jorge Lezaca,David Huckebrink,Andreas Kazantzidis,Detlev Heinemann,Luis F Zarzalejo,María José Jiménez,Robert Pitz-Paal

doi:10.1016/j.solener.2021.11.064

Abstract

Accurate, robust and cost-efficient measurements of diffuse horizontal irradiance (DHI) and global tilted irradiance (GTI) are of great interest for solar energy applications. However, the available measurement techniques exhibit at least one of these shortcomings: restriction of GTI measurement to a single plane, intensive maintenance, high acquisition cost or increased deviations, especially at new measurement sites. To avoid these shortcomings, we suggest a comparably inexpensive and robust setup of a thermopile pyranometer and an all-sky imager (ASI) for measurement of DHI and GTI. The pyranometer measures global horizontal irradiance (GHI) and our method consecutively estimates diffuse sky radiance, DHI, direct normal irradiance (DNI) and GTI, by merging information from the combined setup. The system is developed and validated at two sites in Spain and Germany. Measurement of GTI is benchmarked for seven planes over GTI derived by transposition based on DHI and DNI from a tracker setup with a pyrheliometer and shaded thermopile pyranometer. Our results indicate that the measurement system can be applied at both sites. The proposed method avoids time-consuming radiometric calibrations of the camera by the combination of both sensors and a self-calibration. The measurement system is promising in particular for measurement of GTI. For 10-min average GTI, our approach yields an rRMSD of 1.6...4.8% for planes with tilts in the range of 20∘...61∘. Thus, at both sites and for all planes, it outperforms the tracker-based transposition yielding 2.3...6.5%. DHI is measured significantly more accurately than reported in previous works using an ASI alone.

Highlights

Accurate measurements of global tilted irradiance (GTI) are crucial for solar energy applications
We suggest a comparably inexpensive and robust setup of a thermopile pyranometer and an all-sky imager (ASI) for measurement of diffuse horizontal irradiance (DHI) and GTI
For all pyranometers, which are used at Plataforma Solar de Almería (PSA) to measure global tilted and horizontal irradiance, this calibration is overridden by a calibration relative to the reference global horizontal irradiance (GHI) used in this study, i.e. relative to GHI calculated from direct normal irradiance (DNI) and DHI measured by pyrheliometer and shaded pyranometer of the solar tracker

Summary

Introduction

Accurate measurements of global tilted irradiance (GTI) are crucial for solar energy applications. Knowledge of GTI is important for tasks like resource assessment in the planning process of a PV installation, monitoring a PV plant and quickly identifying abnormalities, as well as to optimize the operation of PV plants For the latter task, forecasting systems relying on measurements of solar irradiance and one or multiple allsky imagers (ASIs), e.g. fisheye cameras with 180◦ field of view used to observe the whole sky, have been demonstrated (Nouri et al, 2020; West et al, 2014). Besides these applications, GTI is essential to compute the overall radiant power received by the surface of a building. It may be advantageous to assess and monitor GTI received by building-integrated photovoltaics (BIPV) to optimize the energy management of buildings (Toledo et al, 2020)

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