A Comparison of Different Rear Irradiation Modeling Methods in a Bifacial PV System

Rania Benbba; Hicham Mastouri; Hassan Radoine; Philippe Drobinski; Jordi Badosa; Abdelkader Outzourhit

doi:10.1007/978-981-99-8501-2_36

A Comparison of Different Rear Irradiation Modeling Methods in a Bifacial PV System

Rania Benbba
, Hicham Mastouri
, Hassan Radoine
, Philippe Drobinski
, Jordi Badosa
, Abdelkader Outzourhit

École Polytechnique

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Bifacial module technology is increasingly used in a multitude of fields (building integrated photovoltaic, agrivoltaic systems, and PV plants). In particular, this type of module can be a better alternative for efficient agri-greenhouses than monofacial ones as a result of the additional energy gain from the rear face. Also, the evaluation of the additional energy gain generated by bifacial modules is crucial for the design and installation of photovoltaic plants based on this technology. This gain depends mainly on the quantification of the irradiation incident on the rear side of the bifacial module. As a result, various optical models, such as those based on the approach of view factors (the average diffused masking angle) and ray tracing were developed to evaluate the irradiation received by the rear face of bifacial modules. In this study, a comparison between the obtained results from the different software tools (SAM, bifacialvf, 3DViewFactor, Bifacial_Radiance) was carried out for an elevated bifacial photovoltaic system composed of three rows. The results show that the radiation received in the three rows is nonuniform. The variation depends on the parameters of the system (tilt angle, ground clearance height, row spacing and Albedo). It was found that the second row was most affected by these parameters. In addition, the results obtained using different softwares showed a difference that can reach about 12% in the case of the Bifacial Radiance and 3DViewFactor.

Original language	English
Title of host publication	Sustainability in Energy and Buildings 2023
Editors	John R. Littlewood, Lakhmi Jain, Robert J. Howlett
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	405-415
Number of pages	11
ISBN (Print)	9789819985005
DOIs	https://doi.org/10.1007/978-981-99-8501-2_36
Publication status	Published - 1 Jan 2024
Event	15th KES International Conference on Sustainability and Energy in Buildings, SEB 2023 - Bari, Italy Duration: 18 Sept 2023 → 20 Sept 2023

Publication series

Name	Smart Innovation, Systems and Technologies
Volume	378
ISSN (Print)	2190-3018
ISSN (Electronic)	2190-3026

Conference

Conference	15th KES International Conference on Sustainability and Energy in Buildings, SEB 2023
Country/Territory	Italy
City	Bari
Period	18/09/23 → 20/09/23

Keywords

Bifacial
Bifacial_radiance
Irradiation
Modeling
Ray tracing
SAM
Simulation
View factor

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1007/978-981-99-8501-2_36

Cite this

Benbba, R., Mastouri, H., Radoine, H., Drobinski, P., Badosa, J., & Outzourhit, A. (2024). A Comparison of Different Rear Irradiation Modeling Methods in a Bifacial PV System. In J. R. Littlewood, L. Jain, & R. J. Howlett (Eds.), Sustainability in Energy and Buildings 2023 (pp. 405-415). (Smart Innovation, Systems and Technologies; Vol. 378). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-981-99-8501-2_36

Benbba, Rania ; Mastouri, Hicham ; Radoine, Hassan et al. / A Comparison of Different Rear Irradiation Modeling Methods in a Bifacial PV System. Sustainability in Energy and Buildings 2023. editor / John R. Littlewood ; Lakhmi Jain ; Robert J. Howlett. Springer Science and Business Media Deutschland GmbH, 2024. pp. 405-415 (Smart Innovation, Systems and Technologies).

@inproceedings{f01416efdafd403687014b69a6a119ec,

title = "A Comparison of Different Rear Irradiation Modeling Methods in a Bifacial PV System",

abstract = "Bifacial module technology is increasingly used in a multitude of fields (building integrated photovoltaic, agrivoltaic systems, and PV plants). In particular, this type of module can be a better alternative for efficient agri-greenhouses than monofacial ones as a result of the additional energy gain from the rear face. Also, the evaluation of the additional energy gain generated by bifacial modules is crucial for the design and installation of photovoltaic plants based on this technology. This gain depends mainly on the quantification of the irradiation incident on the rear side of the bifacial module. As a result, various optical models, such as those based on the approach of view factors (the average diffused masking angle) and ray tracing were developed to evaluate the irradiation received by the rear face of bifacial modules. In this study, a comparison between the obtained results from the different software tools (SAM, bifacialvf, 3DViewFactor, Bifacial\_Radiance) was carried out for an elevated bifacial photovoltaic system composed of three rows. The results show that the radiation received in the three rows is nonuniform. The variation depends on the parameters of the system (tilt angle, ground clearance height, row spacing and Albedo). It was found that the second row was most affected by these parameters. In addition, the results obtained using different softwares showed a difference that can reach about 12\% in the case of the Bifacial Radiance and 3DViewFactor.",

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author = "Rania Benbba and Hicham Mastouri and Hassan Radoine and Philippe Drobinski and Jordi Badosa and Abdelkader Outzourhit",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2024.; 15th KES International Conference on Sustainability and Energy in Buildings, SEB 2023 ; Conference date: 18-09-2023 Through 20-09-2023",

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Benbba, R, Mastouri, H, Radoine, H, Drobinski, P, Badosa, J & Outzourhit, A 2024, A Comparison of Different Rear Irradiation Modeling Methods in a Bifacial PV System. in JR Littlewood, L Jain & RJ Howlett (eds), Sustainability in Energy and Buildings 2023. Smart Innovation, Systems and Technologies, vol. 378, Springer Science and Business Media Deutschland GmbH, pp. 405-415, 15th KES International Conference on Sustainability and Energy in Buildings, SEB 2023, Bari, Italy, 18/09/23. https://doi.org/10.1007/978-981-99-8501-2_36

A Comparison of Different Rear Irradiation Modeling Methods in a Bifacial PV System. / Benbba, Rania; Mastouri, Hicham; Radoine, Hassan et al.
Sustainability in Energy and Buildings 2023. ed. / John R. Littlewood; Lakhmi Jain; Robert J. Howlett. Springer Science and Business Media Deutschland GmbH, 2024. p. 405-415 (Smart Innovation, Systems and Technologies; Vol. 378).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - A Comparison of Different Rear Irradiation Modeling Methods in a Bifacial PV System

AU - Benbba, Rania

AU - Mastouri, Hicham

AU - Radoine, Hassan

AU - Drobinski, Philippe

AU - Badosa, Jordi

AU - Outzourhit, Abdelkader

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2024.

PY - 2024/1/1

Y1 - 2024/1/1

N2 - Bifacial module technology is increasingly used in a multitude of fields (building integrated photovoltaic, agrivoltaic systems, and PV plants). In particular, this type of module can be a better alternative for efficient agri-greenhouses than monofacial ones as a result of the additional energy gain from the rear face. Also, the evaluation of the additional energy gain generated by bifacial modules is crucial for the design and installation of photovoltaic plants based on this technology. This gain depends mainly on the quantification of the irradiation incident on the rear side of the bifacial module. As a result, various optical models, such as those based on the approach of view factors (the average diffused masking angle) and ray tracing were developed to evaluate the irradiation received by the rear face of bifacial modules. In this study, a comparison between the obtained results from the different software tools (SAM, bifacialvf, 3DViewFactor, Bifacial_Radiance) was carried out for an elevated bifacial photovoltaic system composed of three rows. The results show that the radiation received in the three rows is nonuniform. The variation depends on the parameters of the system (tilt angle, ground clearance height, row spacing and Albedo). It was found that the second row was most affected by these parameters. In addition, the results obtained using different softwares showed a difference that can reach about 12% in the case of the Bifacial Radiance and 3DViewFactor.

AB - Bifacial module technology is increasingly used in a multitude of fields (building integrated photovoltaic, agrivoltaic systems, and PV plants). In particular, this type of module can be a better alternative for efficient agri-greenhouses than monofacial ones as a result of the additional energy gain from the rear face. Also, the evaluation of the additional energy gain generated by bifacial modules is crucial for the design and installation of photovoltaic plants based on this technology. This gain depends mainly on the quantification of the irradiation incident on the rear side of the bifacial module. As a result, various optical models, such as those based on the approach of view factors (the average diffused masking angle) and ray tracing were developed to evaluate the irradiation received by the rear face of bifacial modules. In this study, a comparison between the obtained results from the different software tools (SAM, bifacialvf, 3DViewFactor, Bifacial_Radiance) was carried out for an elevated bifacial photovoltaic system composed of three rows. The results show that the radiation received in the three rows is nonuniform. The variation depends on the parameters of the system (tilt angle, ground clearance height, row spacing and Albedo). It was found that the second row was most affected by these parameters. In addition, the results obtained using different softwares showed a difference that can reach about 12% in the case of the Bifacial Radiance and 3DViewFactor.

KW - Bifacial

KW - Bifacial_radiance

KW - Irradiation

KW - Modeling

KW - Ray tracing

KW - SAM

KW - Simulation

KW - View factor

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M3 - Conference contribution

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SN - 9789819985005

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ER -

Benbba R, Mastouri H, Radoine H, Drobinski P, Badosa J, Outzourhit A. A Comparison of Different Rear Irradiation Modeling Methods in a Bifacial PV System. In Littlewood JR, Jain L, Howlett RJ, editors, Sustainability in Energy and Buildings 2023. Springer Science and Business Media Deutschland GmbH. 2024. p. 405-415. (Smart Innovation, Systems and Technologies). doi: 10.1007/978-981-99-8501-2_36

A Comparison of Different Rear Irradiation Modeling Methods in a Bifacial PV System

Abstract

Publication series

Conference

Keywords

UN SDGs

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