Front side metallization of silicon solar cells by direct printing of molten metal

Front side metallization of silicon solar cells by direct printing of molten metal

In this work, a new approach for the front side metallization of silicon solar cells is presented. Molten solder (Sn96Ag3Cu) is directly printed in a non-contact manner on solar cell precursors via StarJet technology. The StarJet technology features a pneumatically driven, heatable printhead with a...

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Veröffentlicht in:Solar energy materials and solar cells 2018-06, Vol.180, p.83-90
Hauptverfasser: Gerdes, B., Jehle, M., Lass, N., Riegger, L., Spribille, A., Linse, M., Clement, F., Zengerle, R., Koltay, P.
Format: Artikel
Sprache:eng
Schlagworte:
Aluminum
Aspect ratio
Busbars
Electric contacts
Front side metallization
Metal printing
Metallizing
Metals
Non-contact printing
Nonimpact printing
Nozzles
Paste consumption
Photovoltaic cells
Plating
Post-processing
Prefabrication
Silicon
Silicon solar cell
Silver
Solar cells
Technology
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container_end_page 90
container_issue
container_start_page 83
container_title Solar energy materials and solar cells
container_volume 180
creator Gerdes, B.
Jehle, M.
Lass, N.
Riegger, L.
Spribille, A.
Linse, M.
Clement, F.
Zengerle, R.
Koltay, P.
description In this work, a new approach for the front side metallization of silicon solar cells is presented. Molten solder (Sn96Ag3Cu) is directly printed in a non-contact manner on solar cell precursors via StarJet technology. The StarJet technology features a pneumatically driven, heatable printhead with a reservoir of molten metal and a star-shaped silicon nozzle chip. Using this printhead, a jet of molten metal with 55 µm ± 5 µm diameter is generated and used to apply busbars as well as contact fingers on prefabricated electroplated seed layers. After deposition via StarJet, printed fingers have a minimum width of 70 µm and a mean aspect ratio of 0.94. The printed metallization is evaluated optically and electrically. Aluminum back surface field silicon solar cells with front side electroplated NiAg seed layers and StarJet metallization (busbars and fingers) show efficiencies of up to 18.1% after degradation. Solder is about 30–40 times cheaper than silver and therefore may allow cost-efficient solar cell metallization. The StarJet metallization on electroplated NiAg seed layers is fully functional and requires no additional post-processing steps. Only 6 mg of Ag per cell are consumed for the seed layer. As a proof-of-principle, a module is demonstrated, which consists of four solar cells that are metallized via StarJet. [Display omitted] •Molten metal printing is used to fabricate front side metallizations of solar cells.•The method requires a minimal amount of silver for the metallization (6 mg).•18,1% efficiency is reached for cells with directly printed metallizations.
doi_str_mv 10.1016/j.solmat.2018.02.022
format Article
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Molten solder (Sn96Ag3Cu) is directly printed in a non-contact manner on solar cell precursors via StarJet technology. The StarJet technology features a pneumatically driven, heatable printhead with a reservoir of molten metal and a star-shaped silicon nozzle chip. Using this printhead, a jet of molten metal with 55 µm ± 5 µm diameter is generated and used to apply busbars as well as contact fingers on prefabricated electroplated seed layers. After deposition via StarJet, printed fingers have a minimum width of 70 µm and a mean aspect ratio of 0.94. The printed metallization is evaluated optically and electrically. Aluminum back surface field silicon solar cells with front side electroplated NiAg seed layers and StarJet metallization (busbars and fingers) show efficiencies of up to 18.1% after degradation. Solder is about 30–40 times cheaper than silver and therefore may allow cost-efficient solar cell metallization. The StarJet metallization on electroplated NiAg seed layers is fully functional and requires no additional post-processing steps. Only 6 mg of Ag per cell are consumed for the seed layer. As a proof-of-principle, a module is demonstrated, which consists of four solar cells that are metallized via StarJet. 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Molten solder (Sn96Ag3Cu) is directly printed in a non-contact manner on solar cell precursors via StarJet technology. The StarJet technology features a pneumatically driven, heatable printhead with a reservoir of molten metal and a star-shaped silicon nozzle chip. Using this printhead, a jet of molten metal with 55 µm ± 5 µm diameter is generated and used to apply busbars as well as contact fingers on prefabricated electroplated seed layers. After deposition via StarJet, printed fingers have a minimum width of 70 µm and a mean aspect ratio of 0.94. The printed metallization is evaluated optically and electrically. Aluminum back surface field silicon solar cells with front side electroplated NiAg seed layers and StarJet metallization (busbars and fingers) show efficiencies of up to 18.1% after degradation. Solder is about 30–40 times cheaper than silver and therefore may allow cost-efficient solar cell metallization. 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source Elsevier ScienceDirect Journals Complete
subjects Aluminum
Aspect ratio
Busbars
Electric contacts
Front side metallization
Metal printing
Metallizing
Metals
Non-contact printing
Nonimpact printing
Nozzles
Paste consumption
Photovoltaic cells
Plating
Post-processing
Prefabrication
Silicon
Silicon solar cell
Silver
Solar cells
Technology
title Front side metallization of silicon solar cells by direct printing of molten metal
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