Performance investigation of novel semitransparent buildings with integrated photovoltaic windows based on fluid-thermal-electric numerical model in the Persian Gulf region

In order to improve traditional construction toward zero- or almost zero-energy buildings, there is a demand for more reliable and renewable energy resources. Solar energy is environmentally friendly, abundant, and has a low environmental impact. The integration of solar panels with semitransparent...

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Bibliographic Details
Published in:Journal of thermal analysis and calorimetry 2023-09, Vol.148 (17), p.9063-9077
Main Authors: Gaaliche, Nesrine, Alsatrawi, Hasan
Format: Article
Language:English
Subjects:
Alternative energy sources
Analytical Chemistry
Building envelopes
Chemistry
Chemistry and Materials Science
Commercial buildings
Conduction heating
Electrical properties
Energy conservation
Energy consumption
Energy sources
Environmental impact
Facades
Glazing
Green buildings
Heat
Heat flux
Inorganic Chemistry
Irradiance
Measurement Science and Instrumentation
Office buildings
Performance prediction
Photovoltaic cells
Physical Chemistry
Polymer Sciences
Renewable energy
Software
Solar energy
Solar panels
Surface temperature
Thermal insulation
Thermal simulation
Windows (apertures)
Windows (computer programs)
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Summary:In order to improve traditional construction toward zero- or almost zero-energy buildings, there is a demand for more reliable and renewable energy resources. Solar energy is environmentally friendly, abundant, and has a low environmental impact. The integration of solar panels with semitransparent windows is used for electricity generation and sunlight penetration, leading to better energy efficiency and reducing energy consumption. This paper aims to analyze the potential of a novel building-integrated photovoltaic semitransparent window as a resource of sustainable energy to save energy use in the office building. In this study, an advanced multi-physics performance prediction approach for a semitransparent building with integrated photovoltaic windows on office building facades was developed in Bahrain’s subtropical desert climate. A parametric study was performed to examine the thermal performance and electrical capacity of semitransparent-integrated photovoltaic solar windows that takes into account the electrical properties, combined radiation and conduction heat transfers, and equivalent heat source methods within solar energy cells. Moreover, a side-by-side comparison study with the reference insulated glass unit investigates the outer and inner surface temperatures. For five design window geometries, 3D-coupled fluid-thermal-electrical multi-physics simulations were run using the COMSOL-coupled solver. The electrical modeling has been developed using MATLAB software, and the energy performance calculation of a sample of a typical commercial building in Manama has been carried out in the ESP-r software environment. The computational results were compared with measurements and manufacturer data. The results obtained illustrate the potential of Xenon-filled double-glazing windows (XDGWs) with integrated PV to save 12% of the energy consumption for cooling purposes in the summer. The results show that the maximum energy produced by solar panels is 248.42 W, and the maximum electrical efficiency of the photovoltaic module is 17.61% at a solar irradiance of 1000 W m −2 . The expected annual solar power generated by the building facade using 500 panels is nearly 140,755 kWh. The results suggested that the XDGW with integrated PV outperformed the reference insulated glass unit in terms of thermal insulation, solar heat flux, and U-factor. On the whole, the simulated outer and inside surface temperatures are in good agreement with the measured data.
ISSN:1388-6150
1588-2926
DOI:10.1007/s10973-023-12290-2