A parallel dispensing System for an improved Front Surface Metallization of Silicon Solar Cells
Seiten
2017
Fraunhofer Verlag
978-3-8396-1106-7 (ISBN)
Fraunhofer Verlag
978-3-8396-1106-7 (ISBN)
Within this thesis, the dispensing technology was enhanced to a high throughput alternative for industrial front side metallization of silicon solar cells. A detailed rheological characterization of applied silver pastes included the introduction of a new characterization method, the pendant thread approach. Multi-nozzle print heads were developed by means of computational fluid dynamics (CFD). Dispensed contact geometries and solar cells were finally analysed in detail and compared to reference samples.
Within this thesis, the dispensing technology was enhanced to a high throughput alternative for industrial front side metallization in silicon (Si) Photovoltaic (PV) production lines. For both, the development of the multi-nozzle print heads by means of computational fluid dynamics (CFD), as well as for the optimization of the geometrical shape of dispensed contact geometries the rheology of the involved printing pastes turned out to be of major importance for the progress of this thesis. With the pendant thread approach, a new method was developed that allows for the extraction of a dynamic extensional yield stress as well as the corresponding surface tension of highly filled pastes (Ca 1). For the development of the multi-nozzle print heads by means of CFD, a Herschel-Bulkley (HB)-model of the respective pastes was set up, using data at process relevant high shear rates obtained from capillary rheometry and taking wall slip behaviour into account. The resulting ten nozzle print head allowed for dispensing of contact fingers with a record width of w_f=27µm at high aspect ratios of AR_el=A_f/(w_f^2)=0.7 and was further applied for processing of commercially available silver (Ag) sinter pastes on industrial solar cells. Finally, a detailed optical contact characterization on cell level and in the encapsulated state was conducted and several electrical characterization methods applied.
Within this thesis, the dispensing technology was enhanced to a high throughput alternative for industrial front side metallization in silicon (Si) Photovoltaic (PV) production lines. For both, the development of the multi-nozzle print heads by means of computational fluid dynamics (CFD), as well as for the optimization of the geometrical shape of dispensed contact geometries the rheology of the involved printing pastes turned out to be of major importance for the progress of this thesis. With the pendant thread approach, a new method was developed that allows for the extraction of a dynamic extensional yield stress as well as the corresponding surface tension of highly filled pastes (Ca 1). For the development of the multi-nozzle print heads by means of CFD, a Herschel-Bulkley (HB)-model of the respective pastes was set up, using data at process relevant high shear rates obtained from capillary rheometry and taking wall slip behaviour into account. The resulting ten nozzle print head allowed for dispensing of contact fingers with a record width of w_f=27µm at high aspect ratios of AR_el=A_f/(w_f^2)=0.7 and was further applied for processing of commercially available silver (Ag) sinter pastes on industrial solar cells. Finally, a detailed optical contact characterization on cell level and in the encapsulated state was conducted and several electrical characterization methods applied.
Erscheinungsdatum | 16.01.2017 |
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Reihe/Serie | Solare Energie- und Systemforschung / Solar Energy and Systems Research |
Zusatzinfo | zahl. Abb. u. Tab. |
Verlagsort | Stuttgart |
Sprache | englisch |
Maße | 148 x 210 mm |
Themenwelt | Naturwissenschaften ► Biologie |
Technik ► Elektrotechnik / Energietechnik | |
Technik ► Maschinenbau | |
Schlagworte | Alternative & renewable energy sources & technolog • alternative & renewable energy sources & technology • Alternative Technologie • Anlagenhersteller • Dosiertechnologie • Drucktechnologie • Erneuerbare Energiequelle • Erneuerbare Energiequellen • Fluidmechanik • Fraunhofer ISE • Maschinenbau • Maschinenwesen • Materialwissenschaften • mechanical engineering • mechanical engineering & materials • Mechanics of Fluids • Medienhersteller • Photovoltaik • Production Engineering • Produzierende Industrie • Rheologie • Wissenschaft |
ISBN-10 | 3-8396-1106-7 / 3839611067 |
ISBN-13 | 978-3-8396-1106-7 / 9783839611067 |
Zustand | Neuware |
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