The use of recycled semiconductor material in crystalline silicon photovoltaic modules production - A life cycle assessment of environmental impacts
Abstract
To offset the negative impact of photovoltaic modules on the environment, it is necessary to introduce a longterm strategy that includes a complete lifecycle assessment of all system components from the production phase through installation and operation to disposal. Recycling of waste products and worn-out systems is an important element of this strategy. As the conclusions from the previous studies have shown, thermal treatment provides an efficient first step in the recycling process, while chemical treatment was more advantageous in the second step. This study aims to assess the environmental impact of recovering and recycling the valuable semiconductor silicon wafer material from photovoltaic solar cells. A comparison was made between producing new solar cells with or without recycled silicon material. The analysis of the photovoltaic cell life cycle scenario including material recycling presented in this article was performed using SimaPro software and data combined and extended from different LCI databases. The idea is that the use of recycled materials, which were energy-consuming in the primary production stage, allows to meaningly reduce the energy input in the secondary life cycle. All stages of the silicon cell life cycle contribute to the Global Warming Potential (GWP) and greenhouse gas emissions reductions through the use of recycled silicon material represented 42%. The total environmental impact of photovoltaic production can be reduced by as much as 58%, mainly through reduced energy consumption in the production process of high purity crystalline silicon.
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- Category:
- Articles
- Type:
- artykuły w czasopismach
- Published in:
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SOLAR ENERGY MATERIALS AND SOLAR CELLS
no. 205,
pages 1 - 9,
ISSN: 0927-0248 - Language:
- English
- Publication year:
- 2020
- Bibliographic description:
- Klugmann-Radziemska E., Kuczyńska-Łażewska A.: The use of recycled semiconductor material in crystalline silicon photovoltaic modules production - A life cycle assessment of environmental impacts// SOLAR ENERGY MATERIALS AND SOLAR CELLS -Vol. 205, (2020), s.1-9
- DOI:
- Digital Object Identifier (open in new tab) 10.1016/j.solmat.2019.110259
- Bibliography: test
-
- A. Sumper, et al. Life-cycle assessment of a photovoltaic system in Catalonia (Spain), 374 open in new tab
- Renew Sustain Energy Rev, 15 (8) (2011), 3888-3896 open in new tab
- A.F. Sherwani, J.A. Usmani, Varum, Life cycle assessment of solar PV based electricity 376 generation systems: a review, Renew Sustain Energy Rev (2010), p. 14 open in new tab
- J. Peng, L. Lu, H. Yang, Review on life cycle assessment of energy payback and open in new tab
- Perpiñan O, et al. Energy Payback Time of Grid Connected PV Systems: Comparison 394 open in new tab
- Between Tracking and Fixed Systems, Progress in Photovoltaics Research and 395 open in new tab
- Applications (2009) 17(2), 137-147, doi: 10.1002/pip.871 396 open in new tab
- Perez M.J.R, et al., Façade-integrated photovoltaics: a life cycle and performance 397 assessment case study. Progress in Photovoltaics: Research And Applications 2012, 398 20(8), 975-90. doi: 10.1002/pip.1167 open in new tab
- Jungbluth N. et al. Life Cycle Assessment for emerging technologies: case studies for 400 photovoltaic and wind power. The International Journal of Life Cycle Assessment (2005), 401 10, 24-34. doi: doi.org/10.1065 open in new tab
- Desideri U., et al. Life cycle assessment of a ground-mounted 1778 kWp photovoltaic 403 plant and comparison with traditional energy production systems. Applied Energy (2012) 404 97, 930-943. doi:10.1016/j.apenergy.2012.01.055 open in new tab
- Bayod-Rújula Á.A., Lorente-Lafuente A.M., Cirez-Oto F. Environmental assessment of 406 grid connected photovoltaic plants with 2-axis tracking versus fixed modules systems. open in new tab
- Energy (2011), 36(5), 3148-58. doi: 10.1016/j.energy.2011.03.004 open in new tab
- Menoufi K., Chemisana D., Rosell J.I., Life cycle assessment of a building integrated 409 concentrated photovoltaic scheme. Applied Energy (2013)111, 505-514. 410 doi:10.1016/j.egypro.2017.09.041 open in new tab
- Graebig M., Bringezu S., Fenner R. Comparative analysis of environmental impacts of 412 maize-biogas and photovoltaics on a land use basis. Solar Energy (2010) 84,1255-1263. 413 doi: 10.1016/j.solener.2010.04.002 open in new tab
- Desideri U., et al. Comparative analysis of concentrating solar power and photovoltaic 415 technologies: Technical and environmental evaluations. Applied Energy (2013) 102,765- 416 84. doi: 10.1016/j.apenergy.2012.08.033 open in new tab
- Wild-Scholten M.J., Alsema E.A., Environmental life cycle inventory of crystalline open in new tab
- Braga, A. F. B., Moreira, S. P., Zampieri, P.R.Bacchin, J. M. G. and Mei, P. R.; New 451 processes for the production of solar-grade polycrystalline silicon: A review. Solar 452 open in new tab
- Energy Materials & Solar Cells (2008), 92, 418-424. doi: 10.1016/j.solmat.2007.10.003 453 open in new tab
- Klugmann-Radziemska, E. and Ostrowski, P., Chemical treatment of crystalline silicon 454 solar cells as a method of recovering pure silicon from photovoltaic modules, Renewable 455 Energy (2010), 35 (8), 1751-1759; doi: 10.1016/j.renene.2009.11.031 open in new tab
- Tao, J. and Yu, S. (2015) Review on feasible recycling pathways and technologies of 457 solar photovoltaic modules, Solar Energy Materials and Solar Cells (2015) 141, 108-124; open in new tab
- 458 doi: 10.1016/j.solmat.2015.05.005 open in new tab
- A. Kuczyńska-Łażewska, E. Klugmann-Radziemska, Z. Sobczak, T. Klimczuk, 460 open in new tab
- Recovery of silver metallization from damaged silicon cells; Solar Energy Materials and 461 Solar Cells (2018) 176,190-195; doi:10.1016/j.solmat.2017.12.004 open in new tab
- European Commission -Joint Research Centre and Institute for Environment and 463 open in new tab
- Sustainability, International Reference Life Cycle Data System (ILCD) Handbook - 464 General guide for Life Cycle Assessment -Detailed guidance. 2010
- Kulczycka, J., Pietrzyk-Sokulska, E., Góralczyk, M., Konieczna, R., Spielmann, M., & 466 open in new tab
- Merl, A., Opracowanie metodyki LCA dla oceny projektów infrastrukturalnych. Kraków 467 2008
- De Schryver, A. M. , Value choices in life cycle impact assessment. Radboud University 469 open in new tab
- Strachala, D., Hylský, J., Vanĕk, J., Fafilek, G., & Jandová, K. Methods for recycling 477 photovoltaic modules and their impact on environment and raw material extraction. Acta 478 open in new tab
- Montanistica Slovaca 2017, 22(3), 257-269
- Klugmann-Radziemska E., Ostrowski P., Kozera F., Method and device for controlled 480 and automatic recovery of materials from silicon photovoltaic cells, PL Patent No. 481 215770, January 24, 2014 open in new tab
- Klugmann-Radziemska, E., Ostrowski, P., Drabczyk, K., Panek, P., & Szkodo, M. 483 (2010). Experimental validation of crystalline silicon solar cells recycling by thermal and 484 chemical methods. Solar Energy Materials and Solar Cells, 94(12), 2275-2282. open in new tab
- https://doi.org/10.1016/j.solmat.2010.07.025 open in new tab
- Jungbluth, N., Life cycle assessment of crystalline photovoltaics in the Swiss ecoinvent 487 database, Progress in Photovoltaics: Research and Applications (2005) 13(8) p. 429-446 488 open in new tab
- Marina M. Lunardi, J. P. Alvarez-Gaitan, J. I. Bilbao, Richard Corkish, Comparative 489 open in new tab
- Life Cycle Assessment of End-of-Life Silicon Solar Photovoltaic Modules, Appl. Sci. 490 2018, 8, 1396; doi:10.3390/app8081396 open in new tab
- Heath, G., Woodhouse, M., & Engel-Cox, J; Value of Recycling PV Modules, Market 492 Size and Need for Design for Recycling. DuraMat workshop Stanford, CA. 2017
- End-of-Life Management, Solar Photovoltaic Panels, International Renewable Energy 494 open in new tab
- Agency IRENA, IEA International Energy Agency 2016 open in new tab
- Gopal G.N., Dubey S., Fundamentals of Photovoltaic Modules and their Applications, 496
- Royal Society of Chemistry 2010 open in new tab
- Bogacka M., Pikoń K., Landrat M., Environmental impact of PV cell waste scenario, open in new tab
- Verified by:
- Gdańsk University of Technology
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