Mv. Landau et al., MEDIUM SEVERITY HYDROTREATING AND HYDROCRACKING OF ISRAELI SHALE OIL - II - TESTING OF NOVEL CATALYST SYSTEMS IN A TRICKLE-BED REACTOR, Fuel, 77(1-2), 1998, pp. 3-13
Hydrotreating Israeli shale oil at 150 atm, an LHSV of 0.5-1.5 h(-1),
a temperature of 340-400 degrees C, and a hydrogen to oil ratio of 150
0 NL L-1 was studied in a trickle-bed reactor pilot plant packed with
two novel catalysts in series. The first catalyst was Ni-Mo supported
on wide-pore alumina and the second catalyst was Co-Mo-Cr supported an
combined zeolite HY-alumina carrier. The desulfurization conversion w
as higher than 99% over the operating conditions tested while denitrog
enation conversion varied over the range 74.3-99.9%. The pseudo-first-
order denitrogenation rate constants measured at 380 degrees C increas
ed from 1.9 to 2.9 h(-1) with increasing distillation temperatures of
shale oil fractions from < 250 degrees C to > 380 degrees C. The appar
ent activation energy decreased from 29.8 to 23.1 kcal mol(-1). The ef
fects of LHSV and temperature on the structure of shale oil components
and hydrocarbons distribution was studied using H-1 and C-13 NMR and
GC-MS methods. The yields of total liquid product, gasoline, jet and d
iesel fuels at 380 degrees C and LHSV = 0.5 h(-1) were 89.4, 9.3, 22.5
and 65.8 wt% of crude shale oil. The volume yield of liquid product p
er crude shale oil at those conditions was 106.9% It contained 160 ppm
sulfur and 80 ppm nitrogen. The quality parameters of motor fuels pro
duced from shale oil by hydrotreating with the two-catalyst system mee
ts certain specifications except gasoline, which displayed low Reid va
por pressure and RON 72. A 400 h stability test at 380 degrees C indic
ated no catalysts deactivation. (C) 1997 Elsevier Science Ltd.