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Project data
Authors Pierce Mayville
Neha Vijay Patil
Joshua M. Pearce
Location Michigan, USA
Status Designed
Modelled
Prototyped
Verified
Verified by MOST
Links https://www.academia.edu/44253625/Distributed_Manufacturing_of_After_Market_Flexible_Floating_Photovoltaic_Modules%7C
https://www.sciencedirect.com/science/article/abs/pii/S2213138820312571?via%3Dihub%7C
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Hardware license CERN-OHL-S
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 Michigan Tech's Open Sustainability Technology LabContact Dr. Joshua Pearce now at Free Appropriate Sustainable Technology.
MOST · Projects & Publications · Methods · Lit. reviews · People · Sponsors · News · Updates on Twitter · YouTube
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 Pearce publicationsFAST · MOST · QAS
Energy Conservation · Energy Policy · Industrial Symbiosis · Life Cycle Analysis · Materials Science · Medical · Open Source · Photovoltaic Systems · Solar Cells · Sustainable Development · Sustainability Education

Floating photovoltaic (FPV) technology is gaining prominence as a means to alleviate land use conflicts while obtaining large solar PV deployments and simultaneously reducing evaporated water loss. In this study, an open source after-market distributed manufacturing method is proposed to be applied to large flexible PV modules to make flexible FPV systems. Specifically this study considers surface floating of flexible thin film solar PV using three types of closed-cell foams: i) neoprene, ii) mincell and iii) polyethylene. The fabricated FPV underwent indoor and outdoor tests for flotation, wave resistance, temperature and resistance to algae accumulation. The average operational temperature was reduced by 10–20 °C for the FPV compared to land-based mounting indicating substantial increases in electricity output compared to ground-based deployment of any type of PV (2–4% for amorphous silicon used here and 5–10% for crystalline silicon based PV). In addition, foam-based FPV racking were also found to reduce costs of racking to $0.37–0.61/W, which is significantly lower than raft-based FPV as well as conventional land-based racking. The results of this preliminary study indicate that foam-backed FPV is exceptionally promising and should be further investigated with different foams, larger systems and more diverse deployments for longer periods to increase PV deployments.

Source

Keywords[edit | edit source]

Floating photovoltaic; FPV; Flexible; Closed-cell foams; Sustainable development; Open-source; Photovoltaic; Racking

See also[edit | edit source]

Open Source Photovoltaic Racking Approaches[edit source]

Page data
Keywords floating photovoltaic, fpv, flexible, closed-cell foams, sustainable development, open-source, photovoltaic, racking, water, solar power, solar energy
SDG Sustainable Development Goal SDG07 Affordable and clean energy, SDG09 Industry innovation and infrastructure
Authors Joshua M. Pearce
Years 2020–2023
License CC-BY-SA-4.0
Affiliations MTU, MOST
Impact Number of views to this page and its redirects. Updated once a month. Views by admins and bots are not counted. Multiple views during the same session are counted as one. {{#metadata:GoogleAnalyticsPageviews}}
Cite as Joshua M. Pearce (2020–2023). "Distributed manufacturing of after market flexible floating photovoltaic modules". Appropedia. Retrieved March 28, 2023.

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