Hydrocracking process and system including separation of heavy poly nuclear aromatics from recycle by oxidation

The invention claimed is: 1. A two stage hydrocracking process for hydrocracking of a vacuum gas oil, a demetallized oil, a deasphalted oil, a coker gas oil, a cycle oil or a visbroken oil hydrocarbon stream, the process comprising: subjecting the vacuum gas oil, demetallized oil, deasphalted oil, coker gas oil, cycle oil or visbroken oil hydrocarbon stream to a first hydrocracking stage to produce a first hydrocracked effluent; fractionating the first hydrocracked effluent to recover one or more hydrocracked product fractions and a bottoms fraction corresponding to the hydrocracked bottoms fraction, wherein the hydrocracker bottoms fraction contains heavy poly nuclear aromatic (HPNA) compounds that are formed during hydrocracking reactions; separating HPNA compounds from the hydrocracked bottoms fraction by contacting the hydrocracked bottoms fraction with an effective quantity of an oxidation agent to promote reaction with HPNA compounds to produce corresponding oxidized HPNA compounds and to form an oxidized hydrocracked bottoms fraction, separating the oxidized hydrocracked bottoms fraction into an HPNA-reduced hydrocracked bottoms portion and an oxidized HPNA portion, and discharging the oxidized HPNA portion; passing all or a portion of the HPNA-reduced hydrocracked bottoms portion to a second hydrocracking stage to produce a second hydrocracked effluent; and subjecting the second hydrocracked effluent to fractionating with the first hydrocracked effluent. 2. The process as in claim 1 , further comprising contacting an additional feed with the oxidation agent. 3. The process as in claim 2 , wherein the additional feed is selected from the group consisting of one or more of straight run vacuum gas oil, treated vacuum gas oil, demetallized oil from solvent demetallizing operations, deasphalted oil from solvent deasphalting operations, coker gas oils from coker operations, cycle oils from fluid catalytic cracking operations including heavy cycle oil, and visbroken oils from visbreaking operations, and wherein the additional feed has a boiling point range within about 350-800° C. 4. The process as in claim 1 , wherein the oxidation agent is liquid phase, and wherein contacting the hydrocracked bottoms fraction with the liquid phase oxidation agent occurs under operating conditions including a reaction temperature in the range of from about 0-150° C., a reaction pressure in the range of from about 1-30 bars, an oxidation agent to aromatic carbon containing compounds (molar ratio) of from about 1:1-15:1, and a feed rate liquid hourly space velocity based on the volume of the reactor in the range of from about 0.5-20 h −1 . 5. The process as in claim 4 , wherein the oxidation agent is selected from the group consisting of peroxides, hydroperoxides, organic peracids, and combinations including at least one of peroxides, hydroperoxides or organic peracids. 6. The process as in claim 4 , wherein contacting the hydrocracked bottoms fraction with the oxidation agent comprises introducing the oxidation agent and the hydrocracked bottoms fraction into an oxidation reaction zone. 7. The process as in claim 4 , wherein contacting the hydrocracked bottoms fraction with the oxidation agent comprises introducing the oxidation agent and the hydrocracked bottoms fraction into a contacting and/or mixing zone to promote intimate mixing of oil and oxidation agent and to produce a mixture, and passing the mixture to an oxidation reaction zone to promote reaction with HPNA compounds to produce corresponding oxidized HPNA compounds and to form the oxidized hydrocracked bottoms fraction. 8. The process as in claim 1 , wherein the oxidation agent is gas phase and is selected from the group consisting of air, oxygen, oxides of nitrogen, ozone, SO 2 , SO 3 and combinations including at least one of air, oxygen, oxides of nitrogen, ozone, SO 2 , or SO 3 , and wherein contacting the hydrocracked bottoms fraction with an effective quantity of a oxidation agent occurs under operating conditions including a reaction temperature in the range of from about 20-600° C., a reaction pressure in the range of from about 0.01 (vacuum)-100 bars, an oxidation agent to aromatic carbon containing compounds (molar ratio) of from about 1:1-15:1, and a feed rate liquid hourly space velocity based on the volume of the reactor in the range of from about 0.5-20 h −1 . 9. The process as in claim 8 , wherein contacting the hydrocracked bottoms fraction with the oxidation agent comprises introducing the oxidation agent and the hydrocracked bottoms fraction into an oxidation reaction zone. 10. The process as in claim 8 , wherein contacting the hydrocracked bottoms fraction with the oxidation agent comprises introducing the oxidation agent and the hydrocracked bottoms fraction into a contacting and/or mixing zone to promote intimate mixing of oil and oxidation agent and to produce a mixture, and passing the mixture to an oxidation reaction zone to promote reaction with HPNA compounds to produce corresponding oxidized HPNA compounds and to form the oxidized hydrocracked bottoms fraction. 11. The process as in claim 10 , wherein the contacting and/or mixing zone comprises a gas distributor vessel in which gaseous oxidation agent is injected at plural locations through distributors into the vessel for adequate mixing to effectively dissolve gaseous oxidation agent in the hydrocracked bottoms fraction. 12. The process as in claim 8 , further comprising discharging excess gas phase oxidation agent either: before separation of the oxidized bottoms fraction into an HPNA-reduced bottoms portion and an oxidized HPNA portion; or during separation of the oxidized bottoms fraction into an HPNA-reduced bottoms portion and an oxidized HPNA portion. 13. The process as in claim 12 , further comprising recycling excess gas phase oxidation agent to the contacting step. 14. The process as in claim 1 , wherein the oxidized HPNA compounds are polar; and wherein separating the oxidized hydrocracked bottoms fraction comprises contacting the oxidized hydrocracked bottoms fraction with an effective quantity of non-polar solvent and under conditions effective to form a precipitated phase containing oxidized HPNA compounds as the oxidized HPNA portion, and a soluble phase containing non-polar solvent and soluble compounds from the oxidized hydrocracked bottoms fraction, wherein the HPNA-reduced hydrocracked bottoms portion is obtained from the soluble phase. 15. The process as in claim 14 , wherein the contacting occurs at temperature at or below the critical point of the non-polar solvent, a solvent-to-oil ratio (V/V) in the range of from about 2:1-50:1, and a pressure in a range that is effective to maintain the solvent/feed mixture in liquid phase. 16. The process as in claim 14 , further comprising separating non-polar solvent from the soluble phase and recovering the HPNA-reduced hydrocracked bottoms portion. 17. The process as in claim 14 , wherein the contacting comprises: admixing the oxidized hydrocracked bottoms fraction and the non-polar solvent; transferring the mixture of the oxidized hydrocracked bottoms fraction and the non-polar solvent to a settler to form the soluble phase and the precipitated phase; discharging the precipitated phase as the oxidized HPNA portion; and separating non-polar solvent from the soluble phase and recovering the HPNA-reduced hydrocracked bottoms portion. 18. The process as in claim 14 , wherein the contacting comprises: admixing the oxidized hydrocracked bottoms fraction and the non-polar