Alkylation process with recycle of hydrogen and recovery of hydrogen chloride

The invention claimed is: 1. An alkylation process, comprising: a. alkylating a reactant in an alkylation reactor ( 300 ) in the presence of an alkylation catalyst comprising an ionic liquid catalyst; b. regenerating a used catalyst ( 70 ) comprising the ionic liquid catalyst and a chloride, from the alkylation reactor ( 300 ), in a hydrogenation reactor ( 100 ) to produce a regenerated catalyst effluent ( 10 ); c. separating at least a portion of the regenerated catalyst effluent ( 10 ), using a hydrocarbon extraction solvent ( 25 ) comprising: i. an alkylate gasoline comprising branched isoparaffins, ii. the reactant for the alkylating comprising an isomerized olefin comprising isobutylene, or iii. mixtures thereof, into a gas fraction comprising a hydrogen gas ( 20 ), a light hydrocarbon fraction comprising a hydrogen chloride ( 30 ), and a regenerated ionic liquid catalyst stream; d. recycling at least a part of the gas fraction comprising the hydrogen gas ( 20 ) to the hydrogenation reactor ( 100 ); and e. recovering at least an amount of the light hydrocarbon fraction comprising the hydrogen chloride ( 30 ) and recycling the at least an amount of the light hydrocarbon fraction to the alkylation reactor ( 300 ); wherein the gas fraction comprising the hydrogen gas ( 20 ) has a lower level of hydrogen chloride that is from 72 to 99 wt % lower than a level of hydrogen chloride in the regenerated catalyst effluent ( 10 ). 2. An alkylation process, comprising: a. alkylating a reactant in an alkylation reactor ( 300 ) in the presence of an alkylation catalyst comprising an ionic liquid catalyst; b. regenerating a used catalyst ( 70 ) comprising the ionic liquid catalyst and a chloride, from the alkylation reactor ( 300 ), in a hydrogenation reactor ( 100 ) to produce a regenerated catalyst effluent ( 10 ); c. mixing a hydrocarbon extraction solvent ( 25 ) comprising: i. an alkylate gasoline comprising branched isoparaffins, ii. the reactant for the alkylating comprising an isomerized olefin comprising isobutylene, or iii. mixtures thereof, with the regenerated catalyst effluent ( 10 ) to make a mixture; d. separating at least a portion of the mixture into a gas fraction comprising a hydrogen gas ( 20 ) and into a light hydrocarbon fraction comprising a hydrogen chloride ( 30 ), the hydrocarbon extraction solvent ( 25 ), and a regenerated ionic liquid catalyst; e. recycling at least a part of the gas fraction comprising the hydrogen gas ( 20 ) to the hydrogenation reactor ( 100 ); f. recycling the regenerated ionic liquid catalyst to the alkylation reactor ( 300 ); and g. recovering at least an amount of the light hydrocarbon fraction comprising the hydrogen chloride ( 30 ) and recycling the at least an amount of the light hydrocarbon fraction to the alkylation reactor ( 300 ); wherein the gas fraction comprising the hydrogen gas ( 20 ) has a lower level of hydrogen chloride that is from 72 to 99 wt % lower than a level of hydrogen chloride in the regenerated catalyst effluent ( 10 ). 3. An alkylation process, comprising: a. alkylating a reactant in an alkylation reactor ( 300 ) in the presence of an alkylation catalyst comprising an ionic liquid catalyst; b. regenerating a used catalyst ( 70 ) comprising the ionic liquid catalyst and a chloride, from the alkylation reactor ( 300 ), in a hydrogenation reactor ( 100 ) to produce a regenerated catalyst effluent ( 10 ); c. separating at least a portion of the regenerated catalyst effluent ( 10 ) into an offgas ( 50 ) comprising a hydrogen gas and into a separated liquid ( 85 ); d. mixing a hydrocarbon extraction solvent ( 25 ) comprising: i. an alkylate gasoline comprising branched isoparaffins, ii. the reactant for the alkylating comprising an isomerized olefin comprising isobutylene, or iii. mixtures thereof, with the offgas ( 50 ) to make a mixture; e. separating the mixture into a gas fraction comprising the hydrogen gas ( 20 ) and into a light hydrocarbon fraction comprising a hydrogen chloride ( 30 ); f. recycling at least a part of the gas fraction comprising the hydrogen gas ( 20 ) to the hydrogenation reactor ( 100 ); g. further separating the separated liquid ( 85 ), in a presence of a conjunct polymer extraction solvent ( 55 ), into an extracted conjunct polymer naphtha ( 45 ) and a regenerated ionic liquid catalyst stream ( 60 ); and h. recovering at least an amount of the light hydrocarbon fraction comprising the hydrogen chloride and recycling the at least an amount of the light hydrocarbon fraction to the alkylation reactor ( 300 ); wherein the gas fraction comprising the hydrogen gas ( 20 ) has a lower level of hydrogen chloride that is from 72 to 99 wt % lower than a level of hydrogen chloride in the offgas ( 50 ). 4. The alkylation process of claim 1 , claim 2 , or claim 3 , wherein the at least an amount of the light hydrocarbon fraction additionally comprises an isoparaffin and an olefin. 5. The alkylation process of claim 1 , wherein the at least an amount of the light hydrocarbon fraction is mixed with a recycled stream comprising a mixture of a second hydrogen chloride and a propane, from the alkylation reactor ( 300 ). 6. The alkylation process of claim 1 , claim 2 , or claim 3 , wherein the at least an amount of the light hydrocarbon fraction comprising the hydrogen chloride is not pre-treated, other than optional separating, before recycling. 7. The alkylation process of claim 1 , claim 2 , or claim 3 , wherein the at least a part of the gas fraction comprising the hydrogen gas ( 2 ) is not dried before recycling. 8. The alkylation process of claim 1 , claim 2 , or claim 3 , wherein at least 80 wt % of the hydrogen chloride, produced in the hydrogenation reactor ( 100 ), is recovered and recycled to the alkylation reactor ( 300 ). 9. The alkylation process of claim 1 , claim 2 , or claim 3 , additionally comprising: removing a recycle gas purge ( 15 ) from the at least a part of the gas fraction comprising the hydrogen gas ( 20 ) prior to its recycling. 10. The alkylation process of claim 1 , additionally comprising compressing the at least a part of the gas fraction comprising the hydrogen gas ( 20 ) before recycling the at least the part of the gas fraction to the hydrogenation reactor ( 100 ). 11. The alkylation process of claim 1 , wherein the separating is done in a distillation column, into which is fed the isomerized olefin and an isoparaffin to be alkylated in the alkylation reactor ( 300 ). 12. The alkylation process of claim 11 , wherein the isomerized olefin comprises 2-butene and the isoparaffin comprises isobutane. 13. The alkylation process of claim 11 , wherein the isomerized olefin and the isoparaffin are fed to the distillation column at one or more locations above where the at least a part of the gas fraction is fed to the distillation column. 14. The alkylation process of claim 1 , or claim 3 , wherein the regenerated ionic liquid catalyst is recycled to the alkylation reactor ( 300 ). 15. The alkylation process of claim 1 , or claim 2 , wherein the regenerated catalyst effluent ( 10 ) comprises an extracted conjunct polymer naphtha ( 45 ). 16. The alkylation process of claim 1 , claim 2 , or claim 3 , wherein the ionic liquid catalyst is selected from the group consisting of hydrocarbyl-substituted-pyridinium chloroaluminate, hydrocarbyl-substituted-imidazolium chloroaluminate, quaternary amine chloroaluminate, trialkyl amine hydrogen chloride chloroaluminate, alkyl pyridine hydrogen chloride chloroaluminate, and mixtures thereof.