Thermal conduction in three-dimensional printed porous samples by high resolution infrared thermography

Thermal conduction in three-dimensional printed porous samples by high resolution infrared thermography

The thermal conductivity (κ) is a key parameter that defines many of the technological uses of three-dimensional (3D) porous architectures. Despite the variety of methods for determining κ, problems generally arise when researchers try to apply them to cellular materials and 3D structures. The prese...

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Main Authors: D. Muñoz Codorníu, J.J. Moyano, M. Belmonte, M.I. Osendi, P. Miranzo
Format: Article
Language:English
Published: Elsevier 2020-11-01
Series:Open Ceramics
Subjects:
3D printed structures
Porous materials
Thermal conductivity
Infrared thermography
Online Access:http://www.sciencedirect.com/science/article/pii/S2666539520300286
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spelling doaj-442915410ebe4d4ca41801eeefdaca892020-12-30T04:23:57ZengElsevierOpen Ceramics2666-53952020-11-014100028Thermal conduction in three-dimensional printed porous samples by high resolution infrared thermographyD. Muñoz Codorníu0J.J. Moyano1M. Belmonte2M.I. Osendi3P. Miranzo4Instituto de Cerámica y Vidrio, CSIC, Campus de Cantoblanco, 28049, Madrid, SpainInstituto de Cerámica y Vidrio, CSIC, Campus de Cantoblanco, 28049, Madrid, SpainInstituto de Cerámica y Vidrio, CSIC, Campus de Cantoblanco, 28049, Madrid, SpainInstituto de Cerámica y Vidrio, CSIC, Campus de Cantoblanco, 28049, Madrid, SpainCorresponding author.; Instituto de Cerámica y Vidrio, CSIC, Campus de Cantoblanco, 28049, Madrid, SpainThe thermal conductivity (κ) is a key parameter that defines many of the technological uses of three-dimensional (3D) porous architectures. Despite the variety of methods for determining κ, problems generally arise when researchers try to apply them to cellular materials and 3D structures. The present work proposes an affordable lab-made device for analysing anisotropic heat flow in 3D porous architectures via high resolution infrared thermography. The method is validated using dense materials of known thermal conductivity. Temperature gradients measured for porous specimens have been correlated to the thermal conductivity estimated from a simple resistors model, assessing the main factors that affect the experimental measurements. The porous specimens of SiC, MAX-phase and graphene-based nanostructures are in-house manufactured by direct ink writing (robocasting).http://www.sciencedirect.com/science/article/pii/S26665395203002863D printed structuresPorous materialsThermal conductivityInfrared thermography
collection DOAJ
language English
format Article
sources DOAJ
author D. Muñoz Codorníu
J.J. Moyano
M. Belmonte
M.I. Osendi
P. Miranzo
spellingShingle D. Muñoz Codorníu
J.J. Moyano
M. Belmonte
M.I. Osendi
P. Miranzo
Thermal conduction in three-dimensional printed porous samples by high resolution infrared thermography
Open Ceramics
3D printed structures
Porous materials
Thermal conductivity
Infrared thermography
author_facet D. Muñoz Codorníu
J.J. Moyano
M. Belmonte
M.I. Osendi
P. Miranzo
author_sort D. Muñoz Codorníu
title Thermal conduction in three-dimensional printed porous samples by high resolution infrared thermography
title_short Thermal conduction in three-dimensional printed porous samples by high resolution infrared thermography
title_full Thermal conduction in three-dimensional printed porous samples by high resolution infrared thermography
title_fullStr Thermal conduction in three-dimensional printed porous samples by high resolution infrared thermography
title_full_unstemmed Thermal conduction in three-dimensional printed porous samples by high resolution infrared thermography
title_sort thermal conduction in three-dimensional printed porous samples by high resolution infrared thermography
publisher Elsevier
series Open Ceramics
issn 2666-5395
publishDate 2020-11-01
description The thermal conductivity (κ) is a key parameter that defines many of the technological uses of three-dimensional (3D) porous architectures. Despite the variety of methods for determining κ, problems generally arise when researchers try to apply them to cellular materials and 3D structures. The present work proposes an affordable lab-made device for analysing anisotropic heat flow in 3D porous architectures via high resolution infrared thermography. The method is validated using dense materials of known thermal conductivity. Temperature gradients measured for porous specimens have been correlated to the thermal conductivity estimated from a simple resistors model, assessing the main factors that affect the experimental measurements. The porous specimens of SiC, MAX-phase and graphene-based nanostructures are in-house manufactured by direct ink writing (robocasting).
topic 3D printed structures
Porous materials
Thermal conductivity
Infrared thermography
url http://www.sciencedirect.com/science/article/pii/S2666539520300286
work_keys_str_mv AT dmunozcodorniu thermalconductioninthreedimensionalprintedporoussamplesbyhighresolutioninfraredthermography
AT jjmoyano thermalconductioninthreedimensionalprintedporoussamplesbyhighresolutioninfraredthermography
AT mbelmonte thermalconductioninthreedimensionalprintedporoussamplesbyhighresolutioninfraredthermography
AT miosendi thermalconductioninthreedimensionalprintedporoussamplesbyhighresolutioninfraredthermography
AT pmiranzo thermalconductioninthreedimensionalprintedporoussamplesbyhighresolutioninfraredthermography
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