dVegetable oils and fats are a renewable resource derived from biomass that
can contribute to reduce the net emission Of CO2 into the atmosphere if us
ed to produce hydrogen for fuel-cell-based energy systems. In this paper, w
e present the results of the steam reforming of several vegetable oils with
three different nickel-based commercial catalysts (ICI 46-1, ICI 46-4, and
UCI G90C) and two research catalysts (UdeS and HT). The experiments were p
erformed in an isothermal fixed-bed tubular reactor at steam-to-carbon (SIC
) ratios of 9, 6, and 3 and temperatures between 500 and 630 degreesC. High
space velocities of 0.76-1.90 MOl(carbon)/(gat h) were used so that conver
sions of the feed would be incomplete. Hydrogen productions were from 0.3 t
o 7.5 MOlH(2)/(g(Ni) h) depending on the operating conditions. The HT catal
yst, which was prepared from a hydrotalcite-like precursor, seems promising
for steam reforming vegetable oils because of its very high activity per g
ram of catalyst. Results for the steam reforming of sunflower, rapeseed, co
rn, and soybean oils at the same catalyst temperature and SIC ratio show th
at oil conversion to gases and hydrogen yields do not depend on the type of
vegetable oil. This indicates that the process might be suitable for produ
cing hydrogen from residual oils and fats from food processing, for which p
rocess economics are more favorable.