E-Book, Englisch, 390 Seiten, Web PDF
Occelli Fluid Catalytic Cracking VI: Preparation and Characterization of Catalysts
1. Auflage 2004
ISBN: 978-0-08-053172-4
Verlag: Elsevier Science & Techn.
Format: PDF
Kopierschutz: 1 - PDF Watermark
E-Book, Englisch, 390 Seiten, Web PDF
Reihe: Studies in Surface Science and Catalysis
ISBN: 978-0-08-053172-4
Verlag: Elsevier Science & Techn.
Format: PDF
Kopierschutz: 1 - PDF Watermark
This volume looks at the recent progress of this technology as reported in the 21 papers presented during the 219th National Meeting of the ACS in New York, September 5-11, 2003.
In addition, the volume focuses on the use of modern spectroscopic techniques for the generation of detailed structural analysis required for the advancement of the science of FCC design.
Other chapters look at the use and importance of solid state nuclear magnetic resonance (NMR), microcalorimetry and atomic force microscopy (AFM) to the study of FCCs and discussing strategies to control pollutant emissions from a refinery FCCU and
looking at advances in FCC preparation.
Autoren/Hrsg.
Weitere Infos & Material
1;Cover;1
2;Contents;8
3;Preface;6
4;Chapter 1. An overview of physical adsorption methods for the characterization of finely divided and porousmaterials and their application to fluid cracking catalysts (FCCs);10
5;Chapter 2. The determination of acidity in fluid cracking catalysts (FCCs) from adsorption microcalorimetry of probe molecules;44
6;Chapter 3. The use ofatomic force microscopy (AFM) to study the surface topography of commercial fluid cracking catalysts (FCCs) and pillared interlayered clay (PILC) catalysts;80
7;Chapter 4. New developments of NMR Spectroscopy applied to zeolites;114
8;Chapter 5. New catalysts may provide insights into role ofnonframework alumina in catalytic cracking catalysis;132
9;Chapter 6. Mechanism of fluid cracking catalysts deactivation by Fe;148
10;Chapter 7. Reduction of NOx emissions from FCCU regenerators with additives;186
11;Chapter 8. Simulating Iron-Induced FCC Accessibility Losses in Lab- Scale Deactivation;174
12;Chapter 9. Oxygen partial pressure effects on vanadium mobility and catalyst deactivation in a simulated FCCU regenerator;198
13;Chapter 10. Comparison of NlR and NMR spectra chemometrics for FCC feed online characterization;212
14;Chapter 11. Cracking behavior of aromatic and organic sulfur compounds under realistic FCC conditions in a microriser reactor;226
15;Chapter 12. Evaluating factors that affect FCC stripper behaviour in a laboratory fluidiscd-bed reactor;242
16;Chapter 13. Effects of FCC variables on the formation of gasoline gum precursors;256
17;Chapter 14. Distributed matrix structures – novel technology for high performance in short contact time FCC applications;266
18;Chapter 15. Feedstock effect on FCC catalyst stripping;296
19;Chapter 16. FCC catalysts with high LPG yield and lower gasoline olefin content;306
20;Chapter 17. Innovations in producing light olefins by fluid catalytic cracking;314
21;Chapter 18. Dual function fluid cracking catalyst (DFCC) containing a microporous additive for olefinselectivity;332
22;Chapter 19. Solid acid catalyst in the alkylation of benzene;350
23;Chapter 20. On the effect of a high reactive sulfur specics on sulfur reduction in gasoline;364
24;Subject Index;378
25;Other volumes in the series;382
