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Rao, Yongchen; Yuan, Chengdong; Sadashivaiah, Gunasheela; Hohlfeld, Dennis; Bechtold, Tamara

Efficient design optimization of a miniaturized thermoelectric generator for electrically active implants based on parametric model order reduction

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  • Media type: E-Article
  • Title: Efficient design optimization of a miniaturized thermoelectric generator for electrically active implants based on parametric model order reduction
  • Contributor: Rao, Yongchen; Yuan, Chengdong; Sadashivaiah, Gunasheela; Hohlfeld, Dennis; Bechtold, Tamara
  • Published: Wiley, 2021
  • Published in: International Journal for Numerical Methods in Biomedical Engineering, 37 (2021) 10
  • Language: English
  • DOI: 10.1002/cnm.3517
  • ISSN: 2040-7939; 2040-7947
  • Keywords: Applied Mathematics ; Computational Theory and Mathematics ; Molecular Biology ; Modeling and Simulation ; Biomedical Engineering ; Software
  • Origination:
  • Footnote:
  • Description: AbstractThis research focuses on the design of a miniaturized thermoelectric generator (TEG) for electrically active implants. Its design optimization is performed using the finite element method. A simplified TEG model is obtained by replacing the thermocouple array with a single representative thermopile, which considers the number and fill factor of the thermocouples as parameters. Instead of rebuilding the geometry of a detailed model with multiple thermocouples, the simplified model adapts the material properties of its representative thermopile, facilitating design optimization. We extend the model by integrating the simplified TEG together with a housing inside a human tissue model for thermoelectric analysis. For computation efficiency and applicability of model order reduction (MOR), a thermal model is derived from the thermoelectric one, with the Peltier effect being considered through an effective thermal conductivity. Through parametric MOR, two parametric reduced‐order models are generated from the full‐scale thermoelectric and thermal model, respectively. Furthermore, we demonstrate the design optimization of TEG both in full‐scale and reduced‐order model for maximal power output and sufficient voltage output.