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Silica alumina catalysts burning rate

Fig. 9. A comparison of the results computed from Eq. (12) for transitional burning (indicated by O) with the observed burning rate behavior for silica-alumina catalyst (solid curve). Fig. 9. A comparison of the results computed from Eq. (12) for transitional burning (indicated by O) with the observed burning rate behavior for silica-alumina catalyst (solid curve).
Weisz (2) carried experiments on silica- alumina beads (many times the size of an average FCC particle). Heobservedthattheintrinsic cokebuming rate was independent of the coke composition and the catalyst characteristics but dependent on initial coke level and the diffusivity. Weisz (3) inanotherstudy, found that the CO /CO ratio during intrinsic coke burning is only a function of temperature. He also observed that this ratio i s affected by the presence oftrace metals like iron and nickel etc. Even though this study was elaborate, it was limited to only silica-alumina catalysts in the form of beads. [Pg.402]

A typical burning rate plot as obtained from a 107 mg. silica-alumina catalyst particle (commercial type catalyst, 349 m. /g. surface area, as used in Sec. IV.2.c) is shown in Figure 20, from which an oxygen diffusivity of. 0024 cm. Vsec. is obtained. In Table VII a direct comparison is made... [Pg.194]

A variety of material could be used as the basis for cracking catalyst, including synthetic silica-alumina, natural clay, or silica-magnesia. If these materials did not contain significant amounts of metals such as chromium or platinum that catalyzed the burning of carbon, the burning rate of the coke is independent of the base as shown in Fig. 7. [Pg.9]

Figure 7.26 Observed coke burning rates for a silica/alumina cracking catalyst with an initial coke content of 3.4 wt% big beads and fine powder. [From P.B. Weisz and R.D. Goodwin, Jr., J. Catal., 2, 397, with the permission of Academic Press, Inc., New York, NY, (1963).]... Figure 7.26 Observed coke burning rates for a silica/alumina cracking catalyst with an initial coke content of 3.4 wt% big beads and fine powder. [From P.B. Weisz and R.D. Goodwin, Jr., J. Catal., 2, 397, with the permission of Academic Press, Inc., New York, NY, (1963).]...
An examination of this problem was provided by Weisz and Cktodwin [11,12]. The pellets were silica-alumina cracking catalyst, and the coke resulted from the cracking of light gas oil and naphtha. Measurements of the burning rate were followed by oxygen consumption rates, as shown in Fig. I. [Pg.252]

Figure 1 Average observed burning rates of conventional silica-alumina cracking catalyst. Initial carbon content, 3.4 Beads dashed line), and ground-up catalyst (full curve) from Weisz and Goodwin [11 ]). Figure 1 Average observed burning rates of conventional silica-alumina cracking catalyst. Initial carbon content, 3.4 Beads dashed line), and ground-up catalyst (full curve) from Weisz and Goodwin [11 ]).
Figure 5.16P Coke burning rates of silica-alumina cracking catalyst. Initial carbon content is 3.4 wt%. (Weisz and Goodwin 1966. Reprinted with permission from Journal of Catalysis. Copyright by Academic Press.)... Figure 5.16P Coke burning rates of silica-alumina cracking catalyst. Initial carbon content is 3.4 wt%. (Weisz and Goodwin 1966. Reprinted with permission from Journal of Catalysis. Copyright by Academic Press.)...

See other pages where Silica alumina catalysts burning rate is mentioned: [Pg.423]   
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