Abstract
An Fe21Cr7Al1Mo0.5Y alumina-forming stainless steel is designed and evaluated as a material for porous supports for oxygen transport membranes. The thermal expansion coefficient, elastic modulus and creep rates of the alloy are presented. The microstructure, porosity and pre-oxidation conditions are optimised simultaneously in-situ during sintering by controlling the growth rate of the oxide scale. Oxidation of metal supports with 20-40% porosity at 850 C and oxygen partial pressure of 10- 11 kPa showed sub-parabolic kinetics and stability over 3000 h. The FeCrAl steel shows vastly superior oxidation resistance compared with an FeCr steel of similar composition and porosity. Modelling of the alloy lifetime as a function of surface area and Al-content was performed, and lifetimes over 30 000 h are predicted for a metal support with 30% porosity operating at a temperature of 750 C, where the oxidation and creep rates are sufficiently low. Ceramic interlayers with graded porosity and pore-size were applied and co-fired with the metal supports, producing substrates that were shown to be viable for a 3 μm dense Ce 0.8Gd0.2O1.9 - δ oxygen transport membrane deposited using sputtering. © 2013 Elsevier B.V.
Original language | English |
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Journal | Solid State Ionics |
Volume | 242 |
Pages (from-to) | 33-44 |
ISSN | 0167-2738 |
DOIs | |
Publication status | Published - 2013 |
Keywords
- Alumina
- Cerium
- Creep
- Gadolinium
- Mechanical properties
- Metals
- Oxidation
- Oxygen
- Porosity
- Scale (deposits)
- Sintering
- Metal support
- Oxygen transport membrane