A process for reducing the sulfur content of a hydrocarbon stream is disclosed. A full range cracked naphtha is contacted with a hydrogenation catalyst to convert at least a portion of the dienes and mercaptans to thioethers and to hydrogenate at least a portion of the dienes. The full range cracked naphtha is fractionated into a light naphtha fraction, a medium naphtha fraction, and a heavy naphtha fraction. The heavy naphtha fraction is hydrodesulfurized. The medium naphtha fraction is mixed with hydrogen and gas oil to form a mixture, which is contacted with a hydrodesulfurization catalyst to produce a medium naphtha fraction having a reduced sulfur concentration. The light, heavy, and medium naphtha fractions may then be recombined to form a hydrodesulfurized product having a sulfur content of less than 10 ppm in some embodiments.

A process for hydrodesulfurizing an olefinic naphtha feedstock while retaining a substantial amount of the olefins, which feedstock has a T95 boiling point below 250 C. boils and contains at least 50 ppmw of organically bound sulfur and from 5% to 60% olefins, said process including (a) selective diolefin hydrogenation, under reaction conditions to convert at least 50% or 90% of the diolefins to paraffins or mono-olefins providing a pre-treated feedstock, (b) hydrodesulfurizing the pre-treated feedstock in a sulfur removal stage in the presence of hydrogen and a hydrodesulfurization catalyst, at hydrodesulfurization reaction conditions to convert at least 50% of the organically bound sulfur to hydrogen sulfide and to produce a desulfurized product stream containing from 0 ppmw to 50 ppmw organically bound sulfur, with the associated benefit of such a process providing a lower octane loss, compared to a process with a lower gas to oil ratio.

A process for hydrodesulfurizing an olefinic naphtha feedstock while retaining a substantial amount of the olefins, which feedstock has a T95 boiling point below 250 C. boils and contains at least 50 ppmw of organically bound sulfur and from 5% to 60% olefins, said process including (a) selective diolefin hydrogenation, under reaction conditions to convert at least 50% or 90% of the diolefins to paraffins or mono-olefins providing a pre-treated feedstock, (b) hydrodesulfurizing the pre-treated feedstock in a sulfur removal stage in the presence of hydrogen and a hydrodesulfurization catalyst, at hydrodesulfurization reaction conditions to convert at least 50% of the organically bound sulfur to hydrogen sulfide and to produce a desulfurized product stream containing from 0 ppmw to 50 ppmw organically bound sulfur, with the associated benefit of such a process providing a lower octane loss, compared to a process with a lower gas to oil ratio.

A process to produce olefins and aromatics via a purification of a hydrocarbon stream including: a) Providing a hydrocarbon stream having a starting boiling point of at least 15? C., a diene value of at least 1.0 preferably at least 1.5 g I2/100 g and a bromine number of at least 5 g Br2/100 g and containing at least 10 wt % of pyrolysis plastic oil where preferably at least 10 wt. % of said hydrocarbon stream has a boiling point of at least 150? C. based on the total weight of said hydrocarbon stream; c) Performing a first hydrotreating step; e) performing a second hydrotreating step; and f) recovering a purified hydrocarbon stream wherein at least a part of this purified hydrocarbon stream is sent to a steam cracker to produce olefins, such as ethylene and propylene, and aromatics.

A method providing for the selective hydroprocessing of cracked naphtha feedstock to make a low-sulfur gasoline blending component. The method includes the use of two catalytic distillation stages in combination with two stripping columns and two fixed-bed reactors integrated in a novel arrangement so as to provide for the treatment of cracked naphtha feedstock that has a high sulfur concentration to yield exceptionally low-sulfur light cracked naphtha and heavy cracked naphtha products. The desulfurized light and heavy cracked naphtha are produced with a minimal amount of hydrogenation of the olefin content and at may suitably be used as gasoline blending components.

A method providing for the selective hydroprocessing of cracked naphtha feedstock to make a low-sulfur gasoline blending component. The method includes the use of two catalytic distillation stages in combination with two stripping columns and two fixed-bed reactors integrated in a novel arrangement so as to provide for the treatment of cracked naphtha feedstock that has a high sulfur concentration to yield exceptionally low-sulfur light cracked naphtha and heavy cracked naphtha products. The desulfurized light and heavy cracked naphtha are produced with a minimal amount of hydrogenation of the olefin content and at may suitably be used as gasoline blending components.

Embodiments of apparatuses and methods for desulfurization of naphtha are provided. In one example, a method comprises fractionating a partially hydrodesulfurized, olefin-enriched naphtha stream in a first vapor-liquid contacting chamber to form a partially hydrodesulfurized, H.sub.2S-depleted, olefin-enriched naphtha stream. The partially hydrodesulfurized, H.sub.2S-depleted, olefin-enriched naphtha stream is contacted with a hydrotreating catalyst to form an additionally hydrodesulfurized, olefin-enriched naphtha stream. The additionally hydrodesulfurized, olefin-enriched naphtha stream is fractionated in a second vapor-liquid contacting chamber to form a hydrodesulfurized, H.sub.2S-depleted, olefin-enriched naphtha product stream. The first and second vapor-liquid contacting chambers are enclosed in a split shell stripper vessel and separated by a dividing wall.

Embodiments of apparatuses and methods for desulfurization of naphtha are provided. In one example, a method comprises fractionating a partially hydrodesulfurized, olefin-enriched naphtha stream in a first vapor-liquid contacting chamber to form a partially hydrodesulfurized, H.sub.2S-depleted, olefin-enriched naphtha stream. The partially hydrodesulfurized, H.sub.2S-depleted, olefin-enriched naphtha stream is contacted with a hydrotreating catalyst to form an additionally hydrodesulfurized, olefin-enriched naphtha stream. The additionally hydrodesulfurized, olefin-enriched naphtha stream is fractionated in a second vapor-liquid contacting chamber to form a hydrodesulfurized, H.sub.2S-depleted, olefin-enriched naphtha product stream. The first and second vapor-liquid contacting chambers are enclosed in a split shell stripper vessel and separated by a dividing wall.

A method of producing a base oil product by hydroprocessing unconverted oil from a hydrocracker in an unconverted oil upgrade reactor to produce upgraded unconverted oil and dewaxing the upgraded unconverted oil to produce the base oil product.

A process for producing isopentane and isoamylene can comprise passing a feed stream comprising C5 hydrocarbons through a hydrodesulfurization assembly to produce a first stream: passing the first stream to a first separation assembly to produce a second stream and a first separated stream: passing the second stream to a deisopentanizer assembly to produce a second separated stream comprising isopentane, a third separated stream comprising C6+ hydrocarbons, and a raffinate stream comprising C5 hydrocarbons; and passing the raffinate stream to a reactor assembly to produce a reaction product stream comprising isoamylene. The present disclosure also provides for a system for producing isopentane and isoamylene.