Js. Buchanan, GASOLINE SELECTIVE ZSM-5 FCC ADDITIVES - MODEL REACTIONS OF C-6-C-10 OLEFINS OVER STEAMED 55 1 AND 450/1 ZSM-5/, Applied catalysis. A, General, 171(1), 1998, pp. 57-64
The reactions of C-6-C-10 olefins over a 55:1 SiO2/Al2O3 ZSM-5 and a 4
50:1 ZSM-5 catalyst were studied, in order to understand the origin of
the relatively low gasoline loss per octane gain observed when high-s
ilica ''gasoline selective'' ZSM-5 is added to the FCC. The ratio of i
somerization to cracking rates for hexene and octene was higher over t
he 450:1 catalyst; isomerization to more highly branched olefins can i
ncrease gasoline octane rating with no gasoline yield loss. Also, the
cracking rates of the higher (e.g. C-8(+)) olefins, compared to cracki
ng of C-7- olefins, were higher for the 450:1 ZSM-5. Thus, for a given
amount of cracking of the higher gasoline olefins, more of the lighte
r (C-5-C-7) olefins will be retained in the gasoline. The cracking of
higher olefins can boost octanes through removal of low-octane long-ch
ain olefins, which also serves to prevent formation of very low octane
long-chain paraffins from these olefins by hydrogen transfer over the
base catalyst, and by formation of high-octane branched C-5-C-6 olefi
ns. Compared to reactions over the 55:1 ZSM-5, the rates of the fastes
t reactions (cracking of higher olefins and isomerization), which tend
to boost octane with little or no gasoline yield loss, are accelerate
d over the 450:1 ZSM-5 relative to the slower reactions (cracking, esp
ecially of C-5-C-7 olefins), which tend to reduce gasoline yield with
less gain in octane. These reactivity patterns can largely explain the
higher gasoline selectivity observed commercially fbr the high-silica
ZSM-5 FCC additives. A likely basis for these differences in reactivi
ty is that the less-active high-silica ZSM-5 is less subject to diffus
ional limitation of reaction rates. (C) 1998 Elsevier Science B.V. All
rights reserved.