MEMoRIAL-M2.10 |Preparation and testing of thermoelectric materials
Projektleiter:
Projektbearbeiter:
M.Sc. Christian Künzel
Finanzierung:
Forschergruppen:
Background
Through the possibility of printing thermoelectric (TE) materials, the specific applications in the field of waste heat recovery can be expanded. A major challenge here is the production of printed TE legs with low thermal conductivity ( ) and a simultaneously high power factor.
Objective
>> Development of a printing process for self-supporting chalcogenide layers as well as the increase of the thermoelectric transport properties
Methods
>> Use of the doctor blading printing technique as a basis with a self-developed colloid disperse printing ink through a wet grinding process by using an organic solvents and a final sintering step for compaction
Results
TE legs were printed as microlayers (50 x 50 x 0.13 mm3) based on a colloidal ink (made of Sb2Te3). A power factor up to 2097 µW/mK2 was determined by 4-point and Seebeck voltage measurements. Hot-disk measurements show a drastic reduction of layer = 0.05 W/mK (by implementing phonon scattering mechanism) compared to the bulk as well as the predictions from our own DFT simulations. Rietveld analyses prove Sb2O3 contents, which can be directly attributed to the organic solvent in the printing ink and could be qualitatively confirmed as crystalline inclusions by EDS as well as SEM measurement. TEM images also show encapsulation of the formed nanostructures.
Conclusions
Considering other recent printing techniques in thermoelectrics, doctor blading showed a power factor increase of up to 65 % compared to screen printing and up to a 17 times power factor increase compared to dispenser printing.
Originality
The research results enable a new approach to the implementation of thermoelectric generators based on printed materials for waste heat recovery.
Keywords
Printing, doctor blading, thermoelectric, power factor, waste heat recovery
Through the possibility of printing thermoelectric (TE) materials, the specific applications in the field of waste heat recovery can be expanded. A major challenge here is the production of printed TE legs with low thermal conductivity ( ) and a simultaneously high power factor.
Objective
>> Development of a printing process for self-supporting chalcogenide layers as well as the increase of the thermoelectric transport properties
Methods
>> Use of the doctor blading printing technique as a basis with a self-developed colloid disperse printing ink through a wet grinding process by using an organic solvents and a final sintering step for compaction
Results
TE legs were printed as microlayers (50 x 50 x 0.13 mm3) based on a colloidal ink (made of Sb2Te3). A power factor up to 2097 µW/mK2 was determined by 4-point and Seebeck voltage measurements. Hot-disk measurements show a drastic reduction of layer = 0.05 W/mK (by implementing phonon scattering mechanism) compared to the bulk as well as the predictions from our own DFT simulations. Rietveld analyses prove Sb2O3 contents, which can be directly attributed to the organic solvent in the printing ink and could be qualitatively confirmed as crystalline inclusions by EDS as well as SEM measurement. TEM images also show encapsulation of the formed nanostructures.
Conclusions
Considering other recent printing techniques in thermoelectrics, doctor blading showed a power factor increase of up to 65 % compared to screen printing and up to a 17 times power factor increase compared to dispenser printing.
Originality
The research results enable a new approach to the implementation of thermoelectric generators based on printed materials for waste heat recovery.
Keywords
Printing, doctor blading, thermoelectric, power factor, waste heat recovery
Kooperationen im Projekt
- Funktionskeramiken mit erhöhter spezifischer Oberfläche (MEMoRIAL-M2.5), Kathleen Dammler
- MEMoRIAL-M2.2 | Characterisation and simulation-based development of Engineering Materials, Rostyslav Nizinkovskyi
- MEMoRIAL-M2.5 | Preparation and characterisation of ceramic foams, Kathleen Dammler
- Max-Planck-Institut Magdeburg, Computational Methods in Systems and Control Theory (CSC), Data, Infrastructure, Software & Computing (DISC), u. a. Martin Köhler
- OVGU/FVST/IfV, Dr.-Ing. Andreas Schlinkert
- OVGU/FNW/IfP, Dr. Gordon Schmidt, Peter Veit
- OVGU/FMB/IWF, u. a. Dr. Ulf Betke
Publikationen
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Kontakt
Prof. Dr. Franziska Scheffler
Otto-von-Guericke-Universität Magdeburg
Fakultät für Verfahrens- und Systemtechnik
Universitätsplatz 2
39106
Magdeburg
Tel.:+49 391 6718824
weitere Projekte
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