Product selectivity during hydrotreating and mild hydrocracking of bitumen-derived gas oil

The hydrotreating (HT) and mild hydrocracking (MHC) of gas oil derived from Athabasca bitumen have been performed in a micro trickle-bed reactor, using a commercial NiMo/Al2O3 catalyst. The operating conditions were varied as follows: temperature range, 340-420degreesC; reactor pressure, 6.5-11.0 MPa; liquid hourly space velocity (LHSV) range, 0.5-2.0 h(-1); and hydrogen/gas oil ratio, 600 mL/mL. The removal values of sulfur and total nitrogen, basic nitrogen, and non-basic nitrogen obtained under optimum conditions were 99, 92, 99, and 88 wt%, respectively. The highest selectivities for sulfur and basic nitrogen removal occurred at the lowest temperature and pressure and the highest LHSV values (i.e., 340degreesC, 6.5 MPa, and 2 h(-1), respectively), whereas those for total and non-basic nitrogen removal occurred at the highest temperature and pressure and the lowest LHSV values (i.e., 420degreesC, 11 MPa, and 0.5 h(-1), respectively). High levels of aromatic saturation were also observed (22.7 wt % aromatics at 400degreesC and 11 Wa). The overall boiling point of each product fraction decreased over the entire temperature range, because of (i) the conversion of sulfur and nitrogen heteroatoms at lower temperatures (less than or equal to 380degreesC) and (ii) MHC at higher temperatures (> 380degreesC). The yield and selectivities of gasoline, kerosene, and light gas oil (LGO) increased as the operating severity increased. The highest yield of gasoline (10 wt %), kerosene (12 wt %), and LGO (19 wt %) were obtained at the highest severity of 420degreesC. Vacuum gas oil (VGO) was the main fraction of the gas oil feed that apparently underwent conversion. No apparent significant change was observed in the net content of the heavy gas oil (HGO) fraction under all operating conditions. A reaction pathway is postulated for the conversion of the gas oil to products via heteroatom removal, saturation of aromatics, and hydrocracking.