Experimental investigation of a building-integrated, transparent, concentrating photovoltaic and thermal collector

As buildings consume roughly one-third of global primary energy, more effective strategies are required to convert on-site solar energy. Here, a multifunctional building façade system, using less than 1% of the semiconductor materials of conventional systems, was tested and developed to expand oppor...

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Bibliographic Details
Published in:Renewable energy 2021-10, Vol.176, p.617-634
Main Authors: Novelli, Nick, Phillips, Kenton, Shultz, Justin, Derby, Melanie M., Salvas, Ryan, Craft, Jesse, Stark, Peter, Jensen, Michael, Derby, Stephen, Dyson, Anna
Format: Article
Language:English
Subjects:
Active integrated façades
Building-integrated concentrating photovoltaics
Dynamic glazing systems
Energy-positive buildings
Net-zero buildings
Solar cogeneration
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Summary:As buildings consume roughly one-third of global primary energy, more effective strategies are required to convert on-site solar energy. Here, a multifunctional building façade system, using less than 1% of the semiconductor materials of conventional systems, was tested and developed to expand opportunities for net-zero commercial architecture by synergistically reducing cooling loads, lighting loads, and contributions to urban heat island effects, while converting ambient solar energy resources for internal demands. The Building Integrated, Transparent, Concentrating, Photovoltaic and Thermal collector (BITCoPT) optically separates diffuse and direct irradiance, transmitting diffuse light for illumination and views. Here, direct irradiance (which is often rejected in commercial buildings to control glare and cooling loads) is intercepted by BITCoPT and converted into electricity and thermal energy. A prototype was tested, demonstrating 43.6% cogeneration efficiency (at a 58 °C operating temperature) relative to direct normal irradiance transmitted through the building's exterior glazing, and 39.0% at 70 °C (which could supply active thermal processes at nominal coefficients of performance). An analytical model was calibrated with observed data, showing good correlation. By substituting parameter values for projected upgrades (to optics, cell type and exterior glazing) into the BITCoPT model, simulated cogeneration efficiency increased to 71.2% at 70 °C (31.2% electrical, 40.0% thermal). [Display omitted] •Electricity and thermal output measured from transparent, concentrating façade-integrated solar collector.•Observed results show good agreement with analytical model.•Cogeneration efficiency of 43.6% observed at 58 °C working temperature.•Efficiency increases projected with expected photovoltaics, lens assembly, and glazing refinements.
ISSN:0960-1481
1879-0682
DOI:10.1016/j.renene.2021.05.046