Experimental application of a laser-based manufacturing process to develop a free customizable, scalable thermoelectric generator demonstrated on a hot shaft

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

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  • Institut für integrierte Produktion Hannover (IPH) gGmbH
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OriginalspracheEnglisch
Aufsatznummere12590
FachzeitschriftEngineering Reports
Jahrgang5
Ausgabenummer4
Frühes Online-Datum13 Nov. 2022
PublikationsstatusVeröffentlicht - 2 Apr. 2023

Abstract

Geometry, design, and processing in addition to the thermoelectric material properties have a significant influence on the economic efficiency and performance of thermoelectric generators (TEGs). While conventional BULK TEGs are elaborate to manufacture and allow only limited variations in geometry, printed TEGs are often restricted in their application and processing temperature due to the use of organic materials. In this work, a proof-of-concept for fabricating modular, customizable, and temperature-stable TEGs is demonstrated by applying an alternative laser process. For this purpose, low temperature cofired ceramics substrates were coated over a large area, freely structured and cut without masks by a laser and sintered to a solid structure in a single optimized thermal post-processing. A scalable design with complex geometry and large cooling surface for application on a hot shaft was realized to prove feasibility. Investigations on sintering characteristics up to a peak temperature of 1173 K, thermoelectric material properties and temperature distribution were carried out for a Ca3Co4O9/Ag-based prototype and evaluated using profilometer, XRD, and IR measurements. For a combined post-processing, an optimal sintering profile could be determined at 1073 K peak temperature with a 20 min holding time. Temperature gradients of up to 100 K could be achieved along a thermocouple. A single TEG module consisting of 12 thermocouples achieved a maximum power of 0.224 μW and open-circuit voltage of 134.41 mV at an average hot-side temperature of 413.6 K and temperature difference of 106.7 K. Three of these modules combined into a common TEG with a total of 36 thermocouples reached a maximum power of 0.58 K and open-circuit voltage of 319.28 mV with a lesser average hot-side temperature of 387.8 K and temperature difference of 83.4 K.

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Experimental application of a laser-based manufacturing process to develop a free customizable, scalable thermoelectric generator demonstrated on a hot shaft. / Abt, Marvin; Kruppa, Katharina; Wolf, Mario et al.
in: Engineering Reports, Jahrgang 5, Nr. 4, e12590, 02.04.2023.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Abt M, Kruppa K, Wolf M, Feldhoff A, Overmeyer L. Experimental application of a laser-based manufacturing process to develop a free customizable, scalable thermoelectric generator demonstrated on a hot shaft. Engineering Reports. 2023 Apr 2;5(4):e12590. Epub 2022 Nov 13. doi: 10.1002/eng2.12590, /10.15488/13364
Abt, Marvin ; Kruppa, Katharina ; Wolf, Mario et al. / Experimental application of a laser-based manufacturing process to develop a free customizable, scalable thermoelectric generator demonstrated on a hot shaft. in: Engineering Reports. 2023 ; Jahrgang 5, Nr. 4.
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title = "Experimental application of a laser-based manufacturing process to develop a free customizable, scalable thermoelectric generator demonstrated on a hot shaft",
abstract = "Geometry, design, and processing in addition to the thermoelectric material properties have a significant influence on the economic efficiency and performance of thermoelectric generators (TEGs). While conventional BULK TEGs are elaborate to manufacture and allow only limited variations in geometry, printed TEGs are often restricted in their application and processing temperature due to the use of organic materials. In this work, a proof-of-concept for fabricating modular, customizable, and temperature-stable TEGs is demonstrated by applying an alternative laser process. For this purpose, low temperature cofired ceramics substrates were coated over a large area, freely structured and cut without masks by a laser and sintered to a solid structure in a single optimized thermal post-processing. A scalable design with complex geometry and large cooling surface for application on a hot shaft was realized to prove feasibility. Investigations on sintering characteristics up to a peak temperature of 1173 K, thermoelectric material properties and temperature distribution were carried out for a Ca3Co4O9/Ag-based prototype and evaluated using profilometer, XRD, and IR measurements. For a combined post-processing, an optimal sintering profile could be determined at 1073 K peak temperature with a 20 min holding time. Temperature gradients of up to 100 K could be achieved along a thermocouple. A single TEG module consisting of 12 thermocouples achieved a maximum power of 0.224 μW and open-circuit voltage of 134.41 mV at an average hot-side temperature of 413.6 K and temperature difference of 106.7 K. Three of these modules combined into a common TEG with a total of 36 thermocouples reached a maximum power of 0.58 K and open-circuit voltage of 319.28 mV with a lesser average hot-side temperature of 387.8 K and temperature difference of 83.4 K.",
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author = "Marvin Abt and Katharina Kruppa and Mario Wolf and Armin Feldhoff and Ludger Overmeyer",
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TY - JOUR

T1 - Experimental application of a laser-based manufacturing process to develop a free customizable, scalable thermoelectric generator demonstrated on a hot shaft

AU - Abt, Marvin

AU - Kruppa, Katharina

AU - Wolf, Mario

AU - Feldhoff, Armin

AU - Overmeyer, Ludger

N1 - Funding Information: This work was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) – project number 325156807. Open Access funding enabled and organized by Projekt DEAL.

PY - 2023/4/2

Y1 - 2023/4/2

N2 - Geometry, design, and processing in addition to the thermoelectric material properties have a significant influence on the economic efficiency and performance of thermoelectric generators (TEGs). While conventional BULK TEGs are elaborate to manufacture and allow only limited variations in geometry, printed TEGs are often restricted in their application and processing temperature due to the use of organic materials. In this work, a proof-of-concept for fabricating modular, customizable, and temperature-stable TEGs is demonstrated by applying an alternative laser process. For this purpose, low temperature cofired ceramics substrates were coated over a large area, freely structured and cut without masks by a laser and sintered to a solid structure in a single optimized thermal post-processing. A scalable design with complex geometry and large cooling surface for application on a hot shaft was realized to prove feasibility. Investigations on sintering characteristics up to a peak temperature of 1173 K, thermoelectric material properties and temperature distribution were carried out for a Ca3Co4O9/Ag-based prototype and evaluated using profilometer, XRD, and IR measurements. For a combined post-processing, an optimal sintering profile could be determined at 1073 K peak temperature with a 20 min holding time. Temperature gradients of up to 100 K could be achieved along a thermocouple. A single TEG module consisting of 12 thermocouples achieved a maximum power of 0.224 μW and open-circuit voltage of 134.41 mV at an average hot-side temperature of 413.6 K and temperature difference of 106.7 K. Three of these modules combined into a common TEG with a total of 36 thermocouples reached a maximum power of 0.58 K and open-circuit voltage of 319.28 mV with a lesser average hot-side temperature of 387.8 K and temperature difference of 83.4 K.

AB - Geometry, design, and processing in addition to the thermoelectric material properties have a significant influence on the economic efficiency and performance of thermoelectric generators (TEGs). While conventional BULK TEGs are elaborate to manufacture and allow only limited variations in geometry, printed TEGs are often restricted in their application and processing temperature due to the use of organic materials. In this work, a proof-of-concept for fabricating modular, customizable, and temperature-stable TEGs is demonstrated by applying an alternative laser process. For this purpose, low temperature cofired ceramics substrates were coated over a large area, freely structured and cut without masks by a laser and sintered to a solid structure in a single optimized thermal post-processing. A scalable design with complex geometry and large cooling surface for application on a hot shaft was realized to prove feasibility. Investigations on sintering characteristics up to a peak temperature of 1173 K, thermoelectric material properties and temperature distribution were carried out for a Ca3Co4O9/Ag-based prototype and evaluated using profilometer, XRD, and IR measurements. For a combined post-processing, an optimal sintering profile could be determined at 1073 K peak temperature with a 20 min holding time. Temperature gradients of up to 100 K could be achieved along a thermocouple. A single TEG module consisting of 12 thermocouples achieved a maximum power of 0.224 μW and open-circuit voltage of 134.41 mV at an average hot-side temperature of 413.6 K and temperature difference of 106.7 K. Three of these modules combined into a common TEG with a total of 36 thermocouples reached a maximum power of 0.58 K and open-circuit voltage of 319.28 mV with a lesser average hot-side temperature of 387.8 K and temperature difference of 83.4 K.

KW - CaCoO

KW - energy harvesting

KW - laser structuring

KW - LTCC

KW - printed ceramics

KW - thermoelectric generator

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U2 - 10.1002/eng2.12590

DO - 10.1002/eng2.12590

M3 - Article

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VL - 5

JO - Engineering Reports

JF - Engineering Reports

SN - 2577-8196

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