Adaptation of a photovoltaic energy balance model for rooftop applications

In this study we adapted and evaluated the utility-scale photovoltaic energy balance model UCRC-Solar for rooftop scenarios. The most important modification is related to the sensible heat exchange. Different modifications are tested and evaluated against measured surface temperatures and power prod...

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Bibliographic Details
Published in:Building and environment 2021-04, Vol.192, p.107628, Article 107628
Main Authors: Heusinger, Jannik, Broadbent, Ashley M., Krayenhoff, E. Scott, Weber, Stephan
Format: Article
Language:English
Subjects:
Arrays
Atmospheric models
Boundary layers
Climate models
Energy balance
Enthalpy
Evaluation
Heat
Heat exchange
Heat flux
Heat transfer
Kinetic energy
Modules
Photovoltaic cells
Photovoltaics
Power generation
PV module temperature
Renewable energy
Roofs
Rooftop PV
Sensible heat
Solar energy
Surface temperature
Thermal characteristics
Wind
Wind direction
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Summary:In this study we adapted and evaluated the utility-scale photovoltaic energy balance model UCRC-Solar for rooftop scenarios. The most important modification is related to the sensible heat exchange. Different modifications are tested and evaluated against measured surface temperatures and power production of a rooftop photovoltaic (PV) module on a tilted roof in Braunschweig, Germany. Strong agreement with an RMSE of 2.7 K and 4 W, respectively, for highly varying meteorological conditions, is achieved by assuming boundary layer development over the PV modules which modulates their convective heat exchange with the atmosphere. The model error is related to the wind direction and turbulent kinetic energy. A higher model error is found for wind directions corresponding to upwind built structures with larger relative roughness. We deem the adapted model, UCRC-Solarroof to be suitable to calculate module temperatures and sensible heat fluxes of individual modules as well as the average of PV arrays on tilted roofs for different roof sizes. UCRC-Solarroof is applied to compare module temperatures, sensible heat fluxes and power production from urban, rooftop PV arrays to rural, ground-based modules. The main causal factor for elevated module temperature on rooftop PV modules relative to their rural, utility-scale counterparts is the smaller sensible heat flux at the lower side of the rooftop PV modules as a result of their proximity to the roof. UCRC-Solarroof has the potential to be integrated in micro-to macroscale meteorological and climate models as well as building energy simulation tools. •Utility-scale model UCRC-Solar is adapted for rooftop PV scenarios.•Evaluation shows strong agreement with module temperatures and power data.•UCRC-Solarroof can simulate individual modules and averages of PV arrays.•Rooftop module temperatures are elevated due to reduced sensible heat flux at the back side.
ISSN:0360-1323
1873-684X
DOI:10.1016/j.buildenv.2021.107628