Laser surface texturing and numerical simulation of heat flux on Cr2AlC MAX phase heat exchangers

The energetic worldwide emergency demands a significant drop in fossil energy to renewable energies as part of the sustainable solutions for global energy consumption. MAX phase materials, such as Cr2AlC, are potential candidates for heat exchanger applications due to their excellent oxidation and c...

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Bibliographic Details
Published in:Journal of the European Ceramic Society 2023-11, Vol.43 (14), p.5894-5903
Main Authors: Mesquita-Guimarães, J., Ferreira, N.M., Reis, R.M.S., Gonzalez-Julian, J., Pinho-da-Cruz, J.
Format: Article
Language:English
Subjects:
Concentrated solar power
Cr2AlC
Heat flux
Laser surface texturing
MAX phase
Microchannels
Plate heat exchanger
Thermal analysis
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Summary:The energetic worldwide emergency demands a significant drop in fossil energy to renewable energies as part of the sustainable solutions for global energy consumption. MAX phase materials, such as Cr2AlC, are potential candidates for heat exchanger applications due to their excellent oxidation and corrosion resistance, good thermal shock response and relatively high thermal conductivity. This study uses laser surface texturing (LST) technology to design plate heat exchanger patterns on the Cr2AlC MAX phase. Furthermore, performing numerical simulations on textured plate models under molten salt conduction and convection conditions, accessing temperature gradient and heat transfer behaviour were conducted on Cr2AlC, as well as on 316 L stainless steel and alumina for comparison. As a result, combined microtextures with a corrugated surface and spaced V-shape channels were obtained using LST in a single step. The parametric study indicated that the optimal channels (groves) were found for 25 W in air and 20 s laser conditions, with approximately 145 µm width and 340 µm depth. Furthermore, the numerical simulation showed that ceramics materials present better heat transfer conditions than 316 L stainless steel, where Cr2AlC and alumina only differ in 1.9% heat flux. In addition, the corrugated surface plate with 2.6% width of the total thickness increases heat transfer by 9.8%.
ISSN:0955-2219
1873-619X
DOI:10.1016/j.jeurceramsoc.2023.06.031