Thermal Degradation Kinetics of Vacuum Residues in the Presence of Chrysotile Supported Ni-Ti Catalyst
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Catalysts
Abstract
For the first time, thermal decomposition of vacuum residue and a mixture of vacuum
residue with binary nanocatalysts based on leached and non-leached chrysotile with applied active
metals was studied using the thermogravimetry method. It is shown that the thermokinetic parameters
of decomposition of vacuum residue and its mixture with binary nanocatalyst are different. The
phase composition of the binary nanocatalyst was established through X-ray phase analysis (XRD):
(Mg3Si2O5 (OH), NiO and Ti (SO4)2). The quantitative content of elements on the chrysotile surface
was determined using X-ray fluorescence analysis: (Ni (4.88%), Ti (7.29%), Si (24.93%), Mg (7.83%),
Fe (0.69%) and S (3.89%)). Using atomic emission spectral analysis, the gross quantitative content of
supported metals on chrysotile was determined: Ni (4.85%) and Ti (4.86%). A transmission electron
microscope showed the presence of finely dispersed particles adsorbed on the surface of and possibly
inside chrysotile nanotubes with sizes ranging from 5 to 70 nm. The acidity of the nanocatalyst
obtained from the leached active-metal-supported chrysotile was 267 mol/g and the specific surface
area of the nanocatalyst was 54 m2/g. The Ozawa–Flynn–Wall (OFW) method was used to calculate
the kinetic parameters of the thermal degradation of vacuum residue and the mixture of vacuum
residue with nanocatalysts. Using the isoconversion method, the average values of activation energies
and the pre-exponential factor were calculated: 147.55 kJ/mol and 3.37 1016 min1 for the initial
vacuum residue; 118.69 kJ/mol and 1.54 1018 min1 for the mixture of vacuum residue with nanocatalyst
obtained from non-leached chrysotile with applied metals; 82.83 kJ/mol and 2.15 1019 min1
for the mixture of vacuum residue with nanocatalyst obtained from leached chrysotile with applied
metals. The kinetic parameters obtained can be used in modeling and designing the processes of
thermal degradation and hydroforming of heavy hydrocarbon raw materials.
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Thermal Degradation Kinetics of Vacuum Residues in the Presence of Chrysotile Supported Ni-Ti Catalyst/Catalysts. - 2023. - №13, 1361. - pp.1-12.