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김상진(S.J. Kim),서정관(S.K. Seo),김봉주(B.J. Kim),백점기(J.K. Paik),Jerzy Czujko(J. Czujko) 한국전산유체공학회 2014 한국전산유체공학회 학술대회논문집 Vol.2014 No.11
The explosion and fire events on offshore platforms are major accidents. They makes most serious damage to human, structure, and environment. Definition of explosion and fire loads is key task to perform the structural analysis to predict the damage. The Korea Ship and Research Institute (KOSORI) at Pusan National University is preparing the large scale explosion test facility for definition of explosion loads. This study is first step for the design of the explosion test facility at KOSORI. The aim of this study is to investigate the explosion loads associated with the effects of congestion and confinement by using FLACS computational fluid dynamics (CFD) program.
Stę,pniowski, Wojciech J.,Choi, Jinsub,Yoo, Hyeonseok,Michalska-Domań,ska, Marta,Chilimoniuk, Paulina,Czujko, Tomasz North-Holland 2016 Materials letters Vol.164 No.-
<P><B>Abstract</B></P> <P>FeAl intermetallic alloy was anodized in 20wt% sulfuric acid at 0°C for 1min at the voltage ranging from 5 to 20V with a step of 2.5V. Based on the FE-SEM images, fast Fourier transformed (2D-FFT) quantitative arrangement analysis of the porous oxide was performed for the oxide formed after the first and the second step of anodization. It was found that for voltages below 15V FFT-derived regularity ratio values for both steps are comparable. For 15V and greater voltages regularity ratio of the obtained anodic oxide is much better while a two-step procedure is employed. Conducted research revealed that two-step self-organized anodization improves regularity of the porous oxide formed on FeAl intermetallic alloy. Moreover, regularity ratio increases rapidly with the anodizing voltage for the second step of anodization.</P> <P><B>Highlights</B></P> <P> <UL> <LI> FeAl intermetallic alloy was anodized in sulfuric acid. </LI> <LI> Porous oxide was obtained. </LI> <LI> Fast Fourier Transform based arrangement analysis was done. </LI> <LI> Since 15V, two-step anodizing improves arrangement. </LI> <LI> The greater voltage the better final arrangement of the pores. </LI> </UL> </P>
Anodization of FeAl intermetallic alloys for bandgap tunable nanoporous mixed aluminum-iron oxide
Stepniowski, W.J.,Choi, J.,Yoo, H.,Oh, K.,Michalska-Domanska, M.,Chilimoniuk, P.,Czujko, T.,Lyszkowski, R.,Jozwiak, S.,Bojar, Z.,Losic, D. Elsevier Sequoia 2016 Journal of Electroanalytical Chemistry Vol.771 No.-
<P>Using a two-step self-organizing anodization of FeAl intermetallic alloy in sulfuric acid, a mixed nanoporous anodic aluminum-iron oxide composite with a voltage-controlled morphology and bandgap was obtained. The chemical composition of nanoporous oxide composites formed with Al, Fe and 0 elements was determined by X-ray photoelectron spectroscopy. It was demonstrated that bandgap of the resulting anodic oxide composites can be tuned from 3.65 eV (samples prepared at 5 V) to 2.06 eV (samples prepared at 17.5 V), which was attributed to the increase in the composition ratio of the oxyhydroxide MOOH (where M = Al and Fe). Thus, water is more involved in the formation of oxide MOOH. After annealing at 600 degrees C, X-ray diffraction confirmed formation of a spinet phase of FeAl2O4. FE-SEM observations of the formed oxide demonstrated that ultra-small nanopores with a diameter of 12.8 +/- 3.0 nm were formed at 5 V. The pore diameter and interpore distance were found to be linearly dependent on the voltage; however, slopes of the fitted curves were much larger than that of nanoporous anodic oxide formed on aluminum. Large current densities recorded during anodization allowed for formation of nanoporous anodic oxide with a growth rate of up to 743.0 +/- 17.9 mu m/h (20 V). (C) 2016 Elsevier B.V. All rights reserved.</P>