System and process for steam cracking and PFO treatment integrating selective hydrogenation, ring opening and naphtha reforming

The invention claimed is: 1. A process for treatment of pyrolysis fuel oil (PFO) from steam cracking that produces light olefins and PFO from a steam cracking feed, the process comprising: optionally separating the PFO into at least a first stream containing C9+ aromatics compounds with one benzene ring and containing hydrocarbons having a lower limit in the range of about 130-150° C. and an upper limit in the range of about 165-215° C., and a second stream containing C10+ aromatic compounds and containing hydrocarbons having a lower limit in the range of about 165-215° C. and an upper limit in the range of about 350-430° C.; selectively hydrogenating all or a portion of the PFO, or all or a portion of the second stream containing C10+ aromatics compounds, using catalysts and conditions, including hydrogen, effective for conversion of polyaromatics compounds contained in the PFO into aromatic compounds with one benzene ring to produce a selectively hydrogenated stream; reacting all or a portion of the selectively hydrogenated stream and optionally all or a portion of the first stream containing C9+ aromatics compounds with one benzene ring, using catalysts and conditions, and in the absence of added hydrogen, effective for ring opening and dealkylation to produce a dealkylated BTX+ stream containing BTX (benzene, toluene and xylenes) compounds and other components; subjecting a naphtha feed to catalytic reforming to produce a reformate stream; and separating at least a portion of the reformate stream and at least a portion of the dealkylated BTX+ stream into BTX compounds. 2. The process as in claim 1 , wherein the PFO is obtained from steam cracking of treated crude oil or other treated heavy oil feeds, and comprises at least 40 wt % of polyaromatics having three or more aromatic rings including triaromatics, naphtheno-triaromatics, tetraaromatics, penta-aromatics and heavier poly-aromatics including asphaltenes and coke. 3. The process as in claim 1 , wherein all or a portion of C20+ polyaromatic compounds are separated from the PFO or from the second stream, prior to selectively hydrogenating all or a portion of the PFO or all or a portion of the second stream containing C10+ aromatics compounds. 4. The process as in claim 1 , wherein the PFO is separated into the first stream, the second stream, and a third stream containing C20+ polyaromatic compounds, and wherein the second stream contains C10+ compounds with no less than 2 and up to 6 benzene rings. 5. The process as in claim 1 , wherein all or a portion of C9+ aromatics with one benzene ring are selectively hydrogenated with all or a portion of the PFO or all or a portion of the second stream containing C10+ aromatics compounds. 6. The process as in claim 1 , wherein the PFO is separated into at least the first stream and the second stream, and wherein all or a portion of the first stream containing C9+ aromatics compounds with one benzene ring bypasses selective hydrogenating and is subjected to ring opening and dealkylation reactions. 7. The process as in claim 1 , wherein the PFO stream or the second stream contains C20+ polyaromatic compounds, and wherein: selective hydrogenating occurs in the presence of a selective hydrogenating catalyst, and wherein selective hydrogenating conditions comprise a reaction temperature (° C.) in the range of about 250-500, a reaction pressure (hydrogen partial pressure, kg/cm 2 ) in the range of about 10-70, a hydrogen feed rate (standard liters per liter of hydrocarbon feed, SLt/Lt) in the range of about 30-5000, and a LHSV in the range of about 0.1-20; and ring opening and dealkylation reactions occur in the absence of added hydrogen, in the presence of a selective ring opening and dealkylation catalyst, and under reaction conditions comprising a reaction temperature (° C.) in the range of about 320-400, a reaction pressure (overall pressure, kg/cm 2 ) in the range of about 1-20, a contact time (seconds) of from about 1-20, and a catalyst-to-feed ratio (weight) of about 1:1 to 10:1. 8. The process as in claim 1 , wherein all or a portion of C20+ polyaromatic compounds are removed prior to selective hydrogenation, and wherein: selective hydrogenating occurs in the presence of a selective hydrogenating catalyst, and wherein selective hydrogenating conditions comprise a reaction temperature (° C.) in the range of about 250-480, a reaction pressure (hydrogen partial pressure, kg/cm 2 ) in the range of about 10-50, a hydrogen feed rate (standard liters per liter of hydrocarbon feed, SLt/Lt) in the range of about 30-4000, and a LHSV in the range of about 0.1-20; and ring opening and dealkylation reactions occur in the absence of added hydrogen, in the presence of a selective ring opening and dealkylation catalyst, and under reaction conditions comprising a reaction temperature (° C.) in the range of about 320-400, a reaction pressure (overall pressure, kg/cm 2 ) in the range of about 1-20, a contact time (seconds) of from about 1-20, and a catalyst-to-feed ratio (weight) of about 1:1 to 10:1. 9. The process as in claim 1 , wherein light gases from selective hydrogenating and/or ring opening and dealkylation reactions are treated and one or more LPG streams are recovered, wherein the one or more LPG streams are subjected to steam cracking. 10. The process as in claim 1 , wherein the selectively hydrogenated stream is separated into an LPG stream that is treated and subjected to steam cracking, and a stream containing one-ring C9+ hydrocarbon compounds that is passed to ring opening and dealkylation reactions as all or a portion of the selectively hydrogenated stream. 11. The process as in claim 1 , wherein separating at least a portion of the dealkylated BTX+ stream into BTX compounds further comprises separating C9 aromatic compounds, and wherein the process further comprises transalkylating the separated C9 aromatic compounds to produce a transalkylated effluent containing additional BTX compounds. 12. The process as in claim 11 , wherein light gases from transalkylating are treated and one or more LPG streams are recovered, and wherein the one or more LPG streams are subjected to steam cracking. 13. The process as in claim 11 , further comprising separating naphtha-range hydrocarbon compounds from the transalkylated effluent prior to separation into BTX compounds, and subjecting all or a portion of said naphtha-range hydrocarbon compounds to steam cracking zone, or wherein all or a portion of said naphtha-range hydrocarbon compounds comprise at least a portion of the naphtha feed to catalytic reforming. 14. The process as in claim 11 , further comprising recovering a raffinate stream comprising non-aromatic compounds from the transalkylated effluent, and subjecting all or a portion of said raffinate stream to steam cracking. 15. The process as in claim 14 , wherein recovering a raffinate stream is by aromatics extraction to separate the dealkylated BTX+ stream into the raffinate stream and an extract stream comprising aromatic compounds, and wherein the extract stream is separated into the BTX compounds. 16. The process as in claim 1 , wherein separating the dealkylated BTX+ stream into BTX compounds further comprises separating C10+ compounds from the dealkylated BTX+ stream. 17. The process as in claim 16 , wherein at least a portion of the separated C10+ compounds are subjected to reactions for ring opening and dealkylation together with the selectively hydrogenated stream. 18. The process as in claim 16 , further comprising treating an initial feed and subjecting a tr