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The solar noise barrier project 4: Modeling of full-scale luminescent solar concentrator noise barrier panels

Author

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  • Bognár, Ádám
  • Kusnadi, Suryadi
  • Slooff, Lenneke H.
  • Tzikas, Chris
  • Loonen, Roel C.G.M.
  • de Jong, Minne M.
  • Hensen, Jan L.M.
  • Debije, Michael G.

Abstract

A full-size (1 × 5 m2) luminescent solar concentrator (LSC) has been constructed and the edge electric outputs from the attached photovoltaic cells monitored for a period of slightly over one year in the solar noise barrier (SONOB) “living lab” outdoor environment. The results of the edge electric output measurements were compared to ray-tracing simulations, revealing imperfections in the system design and production that resulted in the significantly reduced performance of the panel compared to expectations. Results of these calculations suggest edge emission improvements of a factor of 6–9 are possible: at these improved edge outputs, the LSC becomes a viable solar energy generator for the built environment, with significant visual appeal. A grey-box computer model has been developed to predict LSC performance using a realistic device design with reduced internal light scattering and better photovoltaic cell positioning. A second model is used for extrapolation of the LSC solar barrier electric performance with different orientations in different world locations.

Suggested Citation

  • Bognár, Ádám & Kusnadi, Suryadi & Slooff, Lenneke H. & Tzikas, Chris & Loonen, Roel C.G.M. & de Jong, Minne M. & Hensen, Jan L.M. & Debije, Michael G., 2020. "The solar noise barrier project 4: Modeling of full-scale luminescent solar concentrator noise barrier panels," Renewable Energy, Elsevier, vol. 151(C), pages 1141-1149.
    • Handle: RePEc:eee:renene:v:151:y:2020:i:c:p:1141-1149
    DOI: 10.1016/j.renene.2019.11.102
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    References listed on IDEAS

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    1. Kanellis, Michalis & de Jong, Minne M. & Slooff, Lenneke & Debije, Michael G., 2017. "The solar noise barrier project: 1. Effect of incident light orientation on the performance of a large-scale luminescent solar concentrator noise barrier," Renewable Energy, Elsevier, vol. 103(C), pages 647-652.
    2. Rajkumar, Vikram A. & Weijers, Cees & Debije, Michael G., 2015. "Distribution of absorbed heat in luminescent solar concentrator lightguides and effect on temperatures of mounted photovoltaic cells," Renewable Energy, Elsevier, vol. 80(C), pages 308-315.
    3. George Makrides & Bastian Zinsser & Matthew Savvas Harry Norton & George E. Georghiou, 2012. "Performance of Photovoltaics Under Actual Operating Conditions," Chapters, in: Vasilis Fthenakis (ed.), Third Generation Photovoltaics, IntechOpen.
    4. Debije, Michael G. & Tzikas, Chris & Rajkumar, Vikram A. & de Jong, Minne M., 2017. "The solar noise barrier project: 2. The effect of street art on performance of a large scale luminescent solar concentrator prototype," Renewable Energy, Elsevier, vol. 113(C), pages 1288-1292.
    5. Kaldellis, John K. & Kapsali, Marina & Kavadias, Kosmas A., 2014. "Temperature and wind speed impact on the efficiency of PV installations. Experience obtained from outdoor measurements in Greece," Renewable Energy, Elsevier, vol. 66(C), pages 612-624.
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    1. Hyunho Lee & Hyung‐Jun Song, 2021. "Current status and perspective of colored photovoltaic modules," Wiley Interdisciplinary Reviews: Energy and Environment, Wiley Blackwell, vol. 10(6), November.
    2. Giulio Mangherini & Paolo Bernardoni & Eleonora Baccega & Alfredo Andreoli & Valentina Diolaiti & Donato Vincenzi, 2023. "Design of a Ventilated Façade Integrating a Luminescent Solar Concentrator Photovoltaic Panel," Sustainability, MDPI, vol. 15(12), pages 1-18, June.
    3. Hughes, Michael D. & Smith, Duncan E. & Borca-Tasciuc, Diana-Andra, 2020. "Performance of wedge-shaped luminescent solar concentrators employing phosphor films and annual energy estimation case studies," Renewable Energy, Elsevier, vol. 160(C), pages 513-525.

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