Title :
Micro catalytic combustor with tailored porous alumina
Author :
Suzuki, Y. ; Horii, Y. ; Kasagi, N. ; Matsuda, S.
Author_Institution :
Dept. of Mech. Eng., Tokyo Univ., Japan
Abstract :
Micro-scale catalytic combustion of butane is investigated. Porous alumina fabricated through anodic oxidation of thermally-evaporated aluminum is employed for the support of Pt catalyst. A ceramic combustor with an embedded ignition heater is also designed and its prototype is fabricated using a high-precision tape-casting technology. Three-dimensional manifold, which is designed based on a series of CFD analysis, allows us to obtain an uniform velocity distribution in the combustion channel with a minimal pressure drop. The Pt/alumina catalyst layer is successfully integrated onto a ceramic microchannel. It is found in a preliminary experiment that heat release rate up to 830 MW/m3 is achieved, whereas the reaction rate is somewhat smaller than expected from our experimental data in 0.6 mm ID tube.
Keywords :
alumina; aluminium; anodisation; catalysts; ceramics; combustion; computational fluid dynamics; micromechanical devices; porous materials; CFD analysis; Pt-Al2O3; Pt-alumina catalyst layer; anodic oxidation; butane; ceramic combustor; ceramic microchannel; combustion channel; computational fluid dynamics; ignition heater; microcatalytic combustor; microscale catalytic combustion; pressure drop; reaction rate; tailored porous alumina; tape casting technology; thermally evaporated aluminum; velocity distribution; Aluminum; Ceramics; Combustion; Fabrication; Fuels; Hydrocarbons; Isolation technology; Oxidation; Prototypes; Robustness;
Conference_Titel :
Micro Electro Mechanical Systems, 2004. 17th IEEE International Conference on. (MEMS)
Print_ISBN :
0-7803-8265-X
DOI :
10.1109/MEMS.2004.1290585
