75809.pdf

75809.pdf

This chapter deals with heat transfer challenges in the microdomain. It focuses on practical issues regarding this matter when attempting the fabrication of small footprint thermoelectric generators (μTEGs). Thermoelectric devices are designed to bridge a heat source (e.g. hot surface) and a heat si...

Πλήρης περιγραφή

Λεπτομέρειες βιβλιογραφικής εγγραφής
Γλώσσα:English
Έκδοση: InTechOpen 2021
id oapen-20.500.12657-49392
record_format dspace
spelling oapen-20.500.12657-493922021-11-23T13:55:11Z Chapter Managing Heat Transfer Issues in Thermoelectric Microgenerators Marc, Salleras Luis, Fonseca Inci, Donmez-Noyan Marc, Dolcet Joaquin, Santander Denise, Estrada-Wiese Jose-Manuel, Sojo Gerard, Gadea Alex, Morata Albert, Tarancon thermoelectricity, silicon technology, micromachining, silicon nanowires, heat exchangers bic Book Industry Communication::T Technology, engineering, agriculture::TB Technology: general issues::TBC Engineering: general This chapter deals with heat transfer challenges in the microdomain. It focuses on practical issues regarding this matter when attempting the fabrication of small footprint thermoelectric generators (μTEGs). Thermoelectric devices are designed to bridge a heat source (e.g. hot surface) and a heat sink (e.g. ambient) assuring that a significant fraction of the available temperature difference is captured across the active thermoelectric materials. Coexistence of those contrasted temperatures in small devices is challenging. It requires careful decisions about the geometry and the intrinsic thermal properties of the materials involved. The geometrical challenges lead to micromachined architectures, which silicon technologies provide in a controlled way, but leading to fragile structures, too. In addition, extracting heat from small systems is problematic because of the high thermal resistance associated to heat exchanged by natural convection between the surrounding air and small bare surfaces. Forced convection or the application of a cold finger clearly shows the usefulness of assembling a heat exchanger in a way that is effective and compliant with the mechanical constraints of micromachined devices. Simulations and characterization of fabricated structures illustrate the effectiveness of this element integration and its impact on the trade-off between electrical and thermal behavior of the active materials in device performance. 2021-06-02T10:13:52Z 2021-06-02T10:13:52Z 2021 chapter ONIX_20210602_10.5772/intechopen.96246_506 https://library.oapen.org/handle/20.500.12657/49392 eng application/pdf n/a 75809.pdf InTechOpen 10.5772/intechopen.96246 10.5772/intechopen.96246 09f6769d-48ed-467d-b150-4cf2680656a1 FP7-NMP-2013-SMALL-7 604169 open access
institution OAPEN
collection DSpace
language English
description This chapter deals with heat transfer challenges in the microdomain. It focuses on practical issues regarding this matter when attempting the fabrication of small footprint thermoelectric generators (μTEGs). Thermoelectric devices are designed to bridge a heat source (e.g. hot surface) and a heat sink (e.g. ambient) assuring that a significant fraction of the available temperature difference is captured across the active thermoelectric materials. Coexistence of those contrasted temperatures in small devices is challenging. It requires careful decisions about the geometry and the intrinsic thermal properties of the materials involved. The geometrical challenges lead to micromachined architectures, which silicon technologies provide in a controlled way, but leading to fragile structures, too. In addition, extracting heat from small systems is problematic because of the high thermal resistance associated to heat exchanged by natural convection between the surrounding air and small bare surfaces. Forced convection or the application of a cold finger clearly shows the usefulness of assembling a heat exchanger in a way that is effective and compliant with the mechanical constraints of micromachined devices. Simulations and characterization of fabricated structures illustrate the effectiveness of this element integration and its impact on the trade-off between electrical and thermal behavior of the active materials in device performance.
title 75809.pdf
spellingShingle 75809.pdf
title_short 75809.pdf
title_full 75809.pdf
title_fullStr 75809.pdf
title_full_unstemmed 75809.pdf
title_sort 75809.pdf
publisher InTechOpen
publishDate 2021
_version_ 1771297566468603904

Παρόμοια τεκμήρια