Coke zone, analysis

The material balance is consistent with the results obtained by OSA (S2+S4 in g/100 g). For oil A, the coke zone is very narrow and the coke content is very low (Table III). On the contrary, for all the other oils, the coke content reaches higher values such as 4.3 g/ 100 g (oil B), 2.3 g/ioo g (oil C), 2.5 g/ioo g (oil D), 2.4/100 g (oil E). These organic residues have been studied by infrared spectroscopy and elemental analysis to compare their compositions. The areas of the bands characteristic of C-H bands (3000-2720 cm-1), C=C bands (1820-1500 cm j have been measured. Examples of results are given in Fig. 4 and 5 for oils A and B. An increase of the temperature in the porous medium induces a decrease in the atomic H/C ratio, which is always lower than 1.1, whatever the oil (Table III). Similar values have been obtained in pyrolysis studies (4) Simultaneously to the H/C ratio decrease, the bands characteristics of CH and CH- groups progressively disappear. The absorbance of the aromatic C-n bands also decreases. This reflects the transformation by pyrolysis of the heavy residue into an aromatic product which becomes more and more condensed. Depending on the oxygen consumption at the combustion front, the atomic 0/C ratio may be comprised between 0.1 and 0.3 ... 

In this zone, the quantity of extracted oil is generally sufficient to obtain the distribution of the different structural groups (SARA analysis) except for oil A (Fig. 6 to 9) For oil B (Fig. 6), for the first two samples, the amount of extracted products is too low and the analysis is uncertain. It can only be noticed that the asphaltene content is null. On the contrary, just beyond the coke zone (samples III-IV), the asphaltene content respectively reaches 12.9 and 5 4 whereas the asphaltene content of the initial oil is only 0.3. This effect is also observed for oil C (10 versus 6.3%) (Fig. 7), D 24% versus 13.8 ) (Fig. 8), E (24 4 versus 8.1 ) (Fig. 9) For all the oils, the amount of resins+asphaltenes generally remains constant and the amount of saturates increases... 

This work presents a detailed study of coke deposition on Pt/Nb20s catalysts which were deactivated with n-heptane dehydrogenation. Temperature programmed Oxidation (TPO) allowed to the identification of different coke oxidation zones which are related to the distribution of carbonaceous species on the support and on the metallic sites. Chemical analysis of soluble coke was performed allowing to a better understanding of the deactivation processes on niobia supported catalysts. 

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