TH2201005751A - Production of light olefins from crude oil via fluid catalytic cracking and instrumentation - Google Patents

Abstract

DEPCT66 A modified reactor system for efficiently removing contaminants (CCR, nickel, vanadium, nitrogen, sodium, iron, calcium, chlorine, etc.) from the heavy feed of crude oil. The product is sent to a common primary fractionation section. The heavy feed with lower impurities may be processed in a fluid catalytic cracking (FCC) unit, an overall concept using a fluid catalyst reaction platform with a carbon removal method. Also disclosed is a reactor system for efficiently processing crude oil in a fluid catalytic cracking unit with a dual reactor and dual catalyst system to maximize the production of petrochemical building blocks such as ethylene, propylene, butylene, BTX (benzene, toluene and xylene) enriched in naphtha from various crude oils. -----------------------------------------------------------

Claims (29)

1. DEPCT66 1. A useful system for catalytic cracking of all crude oils. The system comprises a separator for separating all crude oil into a light boiling and a heavy boiling fraction, a two-reactor dual catalyst system one and a two-reactor dual catalyst system two, each producing a converted hydrocarbon waste. A general fractionation system for receiving the converted hydrocarbon waste from each of the two-reactor dual catalyst system one and the two-reactor dual catalyst system two. A general fractionation system modified to separate the converted hydrocarbon fraction into two or more hydrocarbon fractions, including one or more olefin fractions and a catalytic cracking feedstock of the treated fluid. A two-reactor dual catalyst system one, wherein the two-reactor dual catalyst system one is modified for contacting the heavy boiling fraction with the catalytic cracking catalyst, the residual fluid, and for contacting the catalyst. Catalyst cracking with a contaminated residual fluid catalytic cracking with a metal trap and a second two-reactor dual catalyst system wherein the second two-reactor dual catalyst system comprises a first reactor for contact with the feedstock for catalytic cracking, a treated reaction fluid with a mixed catalyst system comprising a first catalyst and a second catalyst, a second reactor for contact with the boiling zone with a mixed catalyst system comprising a first catalyst and a second catalyst wherein the first catalyst has a higher relative concentration in the second reactor compared to the first reactor, and a catalyst discharge vessel modified to receive and separate the waste from each of the first and second reactors into a mixture of spent catalyst and converted hydrocarbon waste from the two-reactor dual catalyst system, a second reactor fed to a general separation system. 2. The system of claim 1, wherein the separator for separating the total crude oil into a boiling fraction and a boiling fraction is adjusted to separate the boiling fraction having an ultimate boiling point temperature of 95% in the range from about 300°C to about 420°C from the boiling fraction. 3. The system of claim 1, wherein the second two-reactor dual catalyst system comprises a regenerator for the regeneration of the first spent catalyst and the second spent catalyst, and includes a first outlet for the transport of the first and second spent catalyst mixtures, and a second outlet for the transport of the first and second spent catalyst mixtures, the first reactor, wherein the first reactor is a riser reactor for contacting the heavy boiling zone with the first and second spent catalyst mixtures, wherein the first catalyst has a density greater than the density of the second catalyst, a particle size larger than the particle size of the second catalyst, or both a density greater and a particle size larger than the second catalyst, the riser reactor has an inlet for receiving the catalyst mixture comprising the first and second spent catalysts regenerated from the regenerator, and an outlet for transporting the mixture of converted hydrocarbons and the catalyst mixture. A second reactor, wherein the second reactor is a mobile or fluidized bed reactor for contacting the boiling phase with a concentrated catalyst mixture comprising a first catalyst and a second catalyst, the second reactor has an inlet for receiving the catalyst mixture comprising the first and second catalysts regenerated from the regenerator, an outlet for transporting the converted hydrocarbon mixture, the first catalyst and the second catalyst to the catalyst separation system, the catalyst separation system being modified to separate the first catalyst from the mixture comprising the second catalyst and the converted hydrocarbon according to at least one of the catalyst sizes or catalyst density, producing a first stream comprising the separated first catalyst, and a second stream comprising the second catalyst and the converted hydrocarbon, and an inlet for receiving a first stream comprising the first catalyst. separated thereby increasing the relative concentration of the first catalyst in the second reactor, a venting vessel having one or more inlets for receiving (i) a second stream comprising the second catalyst and the converted hydrocarbon and (ii) a mixture of the converted hydrocarbon and the catalyst mixture, a venting vessel modified to separate and recover a first waste stream comprising the converted hydrocarbon and a second waste stream comprising a mixture of the first and second catalysts that have been used, and a flow line for conveying the mixture of the first and second catalysts that have been used to the regenerator. 4. The system of claim 1, wherein the first two-reactor dual catalyst system comprises a first reactor for contacting the catalytic cracking catalyst of the residual fluid with the heavier boiling hydrocarbon feedstock to convert at least a portion of the hydrocarbon feedstock to a lighter hydrocarbon, a separator for separating the hydrocarbon product vapors, including the lighter hydrocarbons, from the spent catalytic cracking catalyst of the residual fluid, a feed line for feeding the spent cracking catalyst separated from the separator to the catalytic regenerator, a catalyst transfer line for transferring a portion of the spent cracking catalyst from the catalytic regenerator to the decontamination tank, a decontamination tank for contacting the spent catalyst with a contaminant-capturing additive having at least one of the following average particle sizes or densities that is greater than the average particle size or density of the spent catalytic cracking catalyst of the residual fluid, a second separator for separating the top stream from the decontamination tank to the top stream. One stream comprising the catalytic cracking catalyst, residual fluid and gas, a second stream comprising scavenger additive, a recycling line for transfer of the recovered scavenger additive from the second separator to the sludge tank, a bottom line for recovery of the scavenger additive from the sludge tank, and a line for transferring the first stream to the catalyst regenerator. 5. The system of claim 1 wherein the separator for separating all crude oil comprises a hot oil process system. 6. The system of claim 1, wherein the general fractionation system is configured to fractionate the converted hydrocarbon into three or more hydrocarbon fractions; the three or more hydrocarbon fractions include one or more olefin fractions, a feedstock for catalytic cracking, a treated fluid, and one or more fractions of the C5 fraction, the FCC naphtha fraction, the heavy naphtha fraction, the light cycle oil fraction, or the slurry fraction. 7. The system of claim 6 further comprising a flow line for feeding the FCC naphtha portion to the second reactor. 8. The system of claim 6 further comprising an olefins conversion unit for receiving at least one of the C4 and C5 fractions and for converting at least one of the olefins or paraffins herein into at least one of the ethylene or propylene. 9. The system of claim 6 further comprising an aromatic complex modified to transform the heavy naphtha fraction and to recover one or more aromatic product streams. 10. The system of claim 1 further comprising a second separator for separating the heavy boiling fraction into a medium boiling fraction and a residue fraction, wherein the residue fraction is fed as a heavy boiling fraction to a first two-reactor dual catalyst system and wherein the medium boiling fraction is fed to a first reactor of the second two-reactor dual catalyst system. 11. A process for the catalytic cracking of all crude oil, a process comprising separation of the total crude oil into a light boiling fraction and a heavy boiling fraction, conversion of the heavy boiling fraction in a first two-catalytic system and recovery of the converted hydrocarbon waste, conversion of the light boiling fraction in a second two-catalytic system and recovery of the converted hydrocarbon waste, separation of the converted hydrocarbon waste from each of the two-catalytic system first and the two-catalytic system second reactors in a general fractionation system modified to separate the converted hydrocarbon into two or more hydrocarbon fractions, including one or more olefin fractions and a treated catalytic cracking feedstock, wherein the conversion of the heavy boiling fraction in the two-catalytic system first comprises contacting the heavy boiling fraction with the catalytic cracking catalyst, the residual fluid, and contacting the catalytic cracking catalyst residual fluid contaminated with a metal scavenger and wherein the boiling point conversion in a two-reactor dual catalyst system comprises contacting the treated fluid catalytic cracking feedstock with a mixed catalyst system comprising a first catalyst and a second catalyst in a first reactor, contacting the boiling point with the mixed catalyst system comprising a first catalyst and a second catalyst in a second reactor, wherein the first catalyst has a higher relative concentration in the second reactor compared to the first reactor, and separating the waste from each of the first and second reactors into a mixture of spent catalyst and converted hydrocarbon waste from the second two-reactor dual catalyst system that is fed to a general fractionation system. 12. The process of claim 11 wherein the separation of the crude oil into a boiling fraction and a boiling fraction comprises separating the boiling fraction having an ultimate boiling point temperature of 95% in the range from about 300°C to about 420°C from the boiling fraction. 13. The process of claim 11, wherein the second two-reactor dual catalyst system comprises a regenerator for the regeneration of the first spent catalyst and the second spent catalyst, and includes a first outlet for the transport of the first and second spent catalyst mixture, and a second outlet for the transport of the first and second spent catalyst mixture, the first reactor, wherein the first reactor is a riser reactor for contacting the heavy boiling zone with the first and second spent catalyst mixture, wherein the first catalyst has a density greater than the density of the second catalyst, a particle size larger than the particle size of the second catalyst, or both a greater density and a particle size larger than the second catalyst, the riser reactor has an inlet for receiving the catalyst mixture comprising the first and second spent catalysts regenerated from the regenerator, and an outlet for transporting the mixture of converted hydrocarbons and the catalyst mixture. A second reactor, wherein the second reactor is a mobile or fluidized bed reactor for contacting the boiling phase with a concentrated catalyst mixture comprising a first catalyst and a second catalyst. The second reactor has an inlet for receiving the catalyst mixture comprising the first and second catalysts regenerated from the regenerator, an outlet for transporting the converted hydrocarbon mixture, the first catalyst and the second catalyst to the catalyst separation system. The catalyst separation system is configured to separate the first catalyst from the mixture comprising the second catalyst and the converted hydrocarbon according to at least one of the catalyst sizes or catalyst density, producing a first stream comprising the separated first catalyst, a second stream comprising the second catalyst and the converted hydrocarbon, and an inlet for receiving a first stream comprising the first catalyst. separated thereby increasing the relative concentration of the first catalyst in the second reactor, a venting vessel having one or more inlets for receiving (i) a second stream comprising the second catalyst and the converted hydrocarbon and (ii) a mixture of the converted hydrocarbon and the catalyst mixture, a venting vessel modified to separate and recover a first waste stream comprising the converted hydrocarbon and a second waste stream comprising a mixture of the first and second catalysts that have been used, and a flow line for conveying the mixture of the first and second catalysts that have been used to the regenerator. 14. The process of claim 11, wherein the first two-reactor dual catalyst system comprises a first reactor for contacting the residual catalytic cracking catalyst with the hydrocarbon feedstock to convert at least a portion of the hydrocarbon feedstock to lighter hydrocarbons, a separator for separating the lighter hydrocarbons from the spent residual catalytic cracking catalyst, a feed line for feeding the spent residual catalytic cracking catalyst from the separator to the catalytic regenerator, a catalyst transfer line for transferring a portion of the spent residual catalytic cracking catalyst from the catalytic regenerator to the decontamination tank, a decontamination tank for contacting the spent catalyst with a contaminant-capturing additive having at least one of the following average particle sizes or densities that is greater than the average particle size or density of the residual catalytic cracking catalyst, a second separator for separating the top stream from the decontamination tank to the top stream. One stream comprising the catalytic cracking catalyst, residual fluid and gas, a lift and a second stream comprising the scavenger additive, a recycling line for transferring the recovered scavenger additive from the second separator to the sludge tank, a bottom line for recovery of the scavenger additive from the sludge tank and a line for transferring the first stream to the catalyst regenerator. 15. The process of claim 11 wherein the general fractionation system separates the converted hydrocarbon into three or more hydrocarbon fractions; the three or more hydrocarbon fractions include one or more olefins fractions, a feedstock for catalytic cracking, a treated fluid, and one or more fractions of a C4 fraction, a C5 fraction, a FCC naphtha fraction, a heavy naphtha fraction, a light cycle oil fraction, or a thick oil fraction. 16. The process of claim 15, further comprising feeding the C4 portion and the FCC naphtha portion to a second reactor wherein the FCC naphtha portion comprises one or more portions of a light naphtha portion, a medium naphtha portion, a heavy naphtha portion or a full range naphtha portion. 17. The process of claim 15 further comprising feeding light cycle oil (LCO) or treated hydrocarbon liquid or slurry to either the first or second reactor system as a recycled feed or diluent. 18. The process of claim 15, further comprising feeding at least one of portions C4 and C5 to an olefins conversion unit and converting at least one of the olefins or paraffins herein into at least one of the ethylene or propylene. 19. The process of claim 15, further comprising feeding the medium or heavy naphtha fraction to the aromatic complex to transform the medium or heavy naphtha fraction and to recover the one or more aromatic product streams. 20. The process of claim 11 further comprising separating the heavy boiling fraction into a medium boiling fraction and a residue fraction wherein the residue is fed as a heavy boiling fraction to a first two-reactor dual catalyst system and wherein the medium boiling fraction is fed to a first reactor of a second two-reactor dual catalyst system. 21. A useful system for the catalytic cracking of all crude oils. The system shall consist of a separator for separating the total crude oil into a light boiling fraction and a heavy boiling fraction, a regenerator for the regeneration of spent first catalyst and a second catalyst, and a first outlet for the transport of a mixture of the first and second regenerated catalysts, and a second outlet for the transport of a mixture of the first and second regenerated catalysts, a riser reactor for contacting the heavy boiling fraction with the catalyst mixture, wherein the catalyst mixture comprises the first catalyst and the second catalyst, and wherein the first catalyst has a density greater than the density of the second catalyst, a particle size larger than the particle size of the second catalyst, or both a higher density and a larger particle size than the second catalyst, the riser reactor shall have an inlet for receiving the catalyst mixture comprising the first and second catalysts regenerated from the regenerator, and an outlet for transporting the converted hydrocarbon mixture and the A second reactor for contacting the boiling zone with a concentrated catalyst mixture comprising a first catalyst and a second catalyst. The second reactor has an inlet for receiving the catalyst mixture comprising the first and second catalysts regenerated from the regenerator, an outlet for transporting the converted hydrocarbon mixture, the first catalyst and the second catalyst to the catalyst separation system. The catalyst separation system is modified to separate the first catalyst from the mixture comprising the second catalyst and the converted hydrocarbon according to at least one of the catalyst sizes or catalyst density, producing a first stream comprising the separated first catalyst and a second stream comprising the second catalyst and the converted hydrocarbon, an inlet for receiving the first stream comprising the separated first catalyst and for concentrating the first catalyst in the second reactor, a vent vessel having one or more inlets for receiving (i) the second stream comprising a second catalyst and the converted hydrocarbon and (ii) a mixture of the converted hydrocarbon and the catalyst mixture, a modified drain tank for separating and recovering a first waste comprising the converted hydrocarbon and a second waste comprising a mixture of spent first and second catalysts, and a flow line for conveying the spent first and second catalyst mixture to the regenerator. 22. The system of claim 21, wherein the separator comprises a hot oil processing system. 23. The system of claim 21 further comprising a fractionation system modified to receive the first waste and to separate the converted hydrocarbon into three or more hydrocarbon fractions including a light hydrocarbon fraction, a naphtha fraction and a heavy fraction. 24. The system of claim 23 further comprising a flow line for feeding the C4 portion and/or the naphtha portion to the second reactor. 25. The system of claim 21 further comprising a flow line for feeding light cycle oil (LCO) or treated hydrocarbon liquid or slurry to the system, either the first or second reactor as a recycle feed or diluent. 26. The system of claim 22 further comprising a flow line for feeding the heavy portion to the riser reactor. 27. The system of claim 22, wherein the fractionation system is further modified to recover the C5 fraction, the system further comprising an olefins conversion unit for converting the olefins in the C5 fraction into at least one type of ethylene or propylene. 28. The system of claim 22, wherein the fractionation system is further modified to recover the heavy naphtha fraction, the system further comprising an aromatic complex modified to transform the heavy naphtha fraction and recover one or more aromatic product streams. 29. The system of claim 22, wherein the separator for separating the crude oil into a boiling fraction and a boiling fraction is adjusted to separate the boiling fraction having an ultimate boiling point temperature of 95% in the range from about 300°C to about 420°C.