Analytical Optimization of the Design of Film-Laminated Thermoelectric Power Generators

Thermoelectric generators directly convert heat into electricity, typically made from bulk solid thermoelectric materials. They are a widely used technology in exhaust gas heat recovery from automotive vehicles or radioisotope power generation in space satellites. We propose a film-laminated device...

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Bibliographic Details
Published in:Journal of electronic materials 2019-11, Vol.48 (11), p.7312-7319
Main Authors: Koh, Yee Rui, Yazawa, Kazuaki, Shakouri, Ali, Nagahama, Takuma, Maeda, Shinichi, Isaji, Tadayuki, Kasai, Yoshinori
Format: Article
Language:English
Subjects:
Automobiles
Characterization and Evaluation of Materials
Chemistry and Materials Science
Conductivity
Design optimization
Design parameters
Electric contacts
Electronics and Microelectronics
Exhaust gases
Generators
Heat conductivity
Heat recovery
Heat transfer coefficients
Instrumentation
Laminating
Material properties
Materials Science
Mathematical analysis
Optical and Electronic Materials
Parameter sensitivity
Polymer films
Radioisotopes
Solid State Physics
Thermal conductivity
Thermoelectric generators
Thermoelectric materials
Thin films
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Summary:Thermoelectric generators directly convert heat into electricity, typically made from bulk solid thermoelectric materials. They are a widely used technology in exhaust gas heat recovery from automotive vehicles or radioisotope power generation in space satellites. We propose a film-laminated device structure for lower cost and higher volume production. The film-laminated thermoelectric generator design includes a wide variety of thin-film materials and insulator polymer films. Despite the simple fabrication process, the challenges in the bypass heat leak across the insulator film would increase in a film-laminated device structure. The insulator films in the device exhibit low thermal conductivities but cannot be neglected compared to the thermoelectric materials. Comprehensive analysis is conducted on laminated film-based thermoelectric power generators. The study includes the impacts of the geometry design and thermal conductivity to the power output. The sensitivity of design parameters and material properties is investigated. Cost of the power ($/W) from the available heat is estimated. Both of the above are influenced by the effective heat transfer coefficient of the external thermal contacts. The normalized power as a function of the thermal conductivity ratio of the laminate to the thermoelectric materials is determined for a given ZT value. This relationship can be utilized to measure the impact of the laminating material for any material combination. The power output monotonical decreases as the thermal conductivity ratio gets closer to unity. It is highly desirable to use a one order of magnitude lower thermal conductivity for the insulator, especially for thin thermoelectric layer design.
ISSN:0361-5235
1543-186X
DOI:10.1007/s11664-019-07541-8