Process for improving the cetane number of a gas oil cut
Abstract
A process for transforming a gas oil cut from a conversion process or from an aromatic crude is described, the aim of the process being to improve the cetane number of said cut. The process comprises at least one hydrogenation step in which said gas oil cut is passed, in the presence of hydrogen, over a catalyst comprising an amorphous mineral support, at least one compound of a group VIB metal, at least one compound of a non noble group VIII metal and at least phosphorous or a compound of phosphorous, the process then comprising a hydrocracking step in which the hydrogenated feed is passed, in the presence of hydrogen, over a catalyst comprising an acidic support, at least one compound of a group VIB metal and at least one compound of a non noble group VIII metal.
Claims
exact text as granted — not AI-modified1 - 14 . (Cancelled).
15 . A fuel obtained using a process for converting a gas oil cut into a high cetane number fuel which is dearomatised and desulphurised, said process comprising
at least one first step (a) in which hydrogenation is performed to produce a hydrogenated product, wherein said gas oil cut is passed, in the presence of hydrogen, over a catalyst comprising an amorphous mineral support, at least one metal or compound of a metal from group VIB of the periodic table in a quantity, expressed as the weight of metal with respect to the weight of finished catalyst, of about 0.5% to 40%, at least one non noble metal or compound of a non noble metal from group VIII of the periodic table in a quantity, expressed as the weight of metal with respect to the weight of finished catalyst, of about 0.01% to 30%, and phosphorous or at least one phosphorous compound in a quantity, expressed as the weight of phosphorous pentoxide with respect to the weight of the support, of about 0.001% to 20%; and at least one second step (b) in which hydrocracking is performed to produce an effluent containing light compounds, wherein said hydrogenated product from the first step is passed, in the presence of hydrogen, over a catalyst comprising a mineral support which is partly zeolitic, at least one metal or compound of a metal from group VIB of the periodic table in a quantity, expressed as the weight of metal with respect to the weight of finished catalyst, of about 0.5% to 40% and at least one non noble metal or compound of a non noble metal from group VIII in a quantity, expressed as the weight of metal with respect to the weight of finished catalyst, of about 0.02% to 20%, and then separating said light compounds from the hydrocracking effluent, wherein said gas oil cut introduced into the hydrogenation step has an initial boiling point of at least 150° C., at least 90 wt % of which boils at at most 370° C., wherein total conversion of the gas oil cut in the hydrocracking and hydrogenation steps is less than 50% w/w.
16 . A fuel according to claim 15 , wherein the boiling point of the gas oil cut is in the range 180-370° C.
17 . A fuel according to claim 15 , wherein the gas oil cut has an aromatic compound content of at least 20% by weight and less than 40% by weight.
18 . A fuel according to claim 15 , wherein the metal from group VIB of the catalyst of step b) is molybdenum or tungsten and the metal from group VIII of the catalyst of step b) is nickel, cobalt or iron.
19 . A fuel according to claim 15 , wherein the operating conditions for steps a) and b) comprise a temperature of about 250C to about 450C, a total pressure of about 0.5 to 20 MPa and a global hourly space velocity of liquid feed of about 0.1 to about 30 h −1 .
20 . A fuel according to claim 15 , wherein the catalyst of step a) comprises boron or at least one compound of boron.
21 . A fuel according to claim 15 , wherein said process further comprises subjecting effluent from the hydrocracking step to a hydrogenation step.
22 . A fuel obtained by a process for converting a gas oil cut into a high cetane number fuel which is dearomatised and desulphurised, said process comprising
at least one first step (a) in which hydrogenation is performed to produce a hydrogenated product, wherein said gas oil cut is passed, in the presence of hydrogen, over a catalyst comprising an amorphous mineral support, at least one metal or compound of a metal from group VIB of the periodic table in a quantity, expressed as the weight of metal with respect to the weight of finished catalyst, of about 0.5% to 40%, at least one non noble metal or compound of a non noble metal from group VIII of the periodic table in a quantity, expressed as the weight of metal with respect to the finished catalyst, of about 0.01% to 30%, and phosphorous or at least one phosphorous compound in a quantity, expressed as the weight of phosphorous pentoxide with respect to the weight of the support, of about 0.001% to 20%; and at least one second step (b) in which hydrocracking is performed to produce an effluent containing light compounds, wherein said hydrogenated product from the first step is passed, in the presence of hydrogen, over a catalyst comprising a mineral support which is partly zeolitic, at least one metal or compound of a metal group VIB of the periodic table in a quantity, expressed as the weight of metal with respect to the weight of finished catalyst, of about 0.5% to 40% and at least one non noble metal or compound of a non noble metal from group VIII in a quantity, expressed as the weight of metal with respect to the weight of finished catalyst, of about 0.02% to 20%, and then separating said light compounds from the hydrocracking effluent, wherein said gas oil cut introduced into the hydrogenation step has an initial boiling point of at least 150° C., at least 90 wt % of which boils at at most 370° C.Join the waitlist — get patent alerts
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