TH2301006160A - The improvement of aromatics, which starts with the catalytic cracking of gasoline molecules into aromatic complexes. - Google Patents

Abstract

DEPCT67 This invention relates to a process and apparatus for the conditioning and separation of aromatic compounds originating from a gasoline feedstock, comprising the following steps/units: selective hydrogenation (A) of the gasoline feedstock (1) in the presence of hydrogen (2) to produce selective hydrogenation by-products (3); fractional distillation (B) of selective hydrogenation by-products (3) to produce at least a compound comprising a C5 distillation phase (4) having 5 or fewer carbon atoms and a compound comprising a C6+ distillation phase (5) having at least 6 carbon atoms; hydrogenation (C) of the C6+ distillation phase (5) to produce hydrogenation by-products (6); extraction of aromatics (D) from hydrogenation by-products (6) to produce at least an aromatic stream (17) concentrated in aromatic compounds and a raffinate (10) concentrated in non-aromatic compounds, compared with Composition of substances produced from hydrogenation (6)

Claims (15)

1. DEPCT67 1. A process for the conditioning and separation of aromatic compounds, starting from a gasoline feedstock, comprising the following steps: optional hydrogenation (A) of the gasoline feedstock (1) to hydrogenate at least the diolefins contained in the gasoline feedstock (1) in the presence of hydrogen (2) and to produce an optional hydrogenation by-product (3); fractional distillation (B) of the optional hydrogenation by-product (3) to produce at least a compound consisting of the fractional distillation range C5 (4) having 5 carbon atoms or less and a compound consisting of the fractional distillation range C6+ (5) having at least 6 carbon atoms; hydrogenation (C) of the fractional distillation range C6+ (5) to hydrogenate at least the olefins contained in the fractional distillation range C6+ (5) in the presence of hydrogen and to produce an optional hydrogenation by-product Hydrogenation (6) Extraction of aromatics (D) from hydrogenation exit (6) to produce at least a minimum of aromatic currents (17) concentrated in aromatic compounds compared to hydrogenation exit (6) and raffinate (10) concentrated in non-aromatic compounds compared to the composition of the hydrogenation exit (6). 2. The process of claim 1, wherein the gasoline feedstock (1) comprises a gasoline distillation phase produced by a catalytic cracking unit. 3. The process according to claim 1 or claim 2, wherein the hydrogenation step, optionally (A), is carried out at least one of the following operating conditions: the presence of at least one catalyst comprising a support and a reaction phase comprising at least one element from Group VIII, a temperature between 50 and 250 °C, an LHSV fluid velocity per hour between 0.5 and 20 per hour, a pressure between 0.4 and 5 MPa, and an H2/gasoline feedstock ratio by volume between 2 and 100 standard cubic meters/cubic meter. 4. The process according to any one of the preceding claims, wherein the fractional distillation step (B) is controlled to produce the fractional distillate C6+(5) which contains less than or equal to 5000 parts per million by weight of a compound having a boiling point greater than 217°C. 5. The process according to any of the preceding claims, wherein the hydrogenation step (C) is carried out at least one of the following operating conditions: the presence of at least one catalyst, a reactant comprising a support and a reaction phase comprising at least one element from Group VIII, a temperature between 100 and 400 °C, a space velocity of the LHSV liquid between 0.1 and 20 per hour, a pressure between 0.1 and 5 MPa absolute, and a volumetric H2/gasoline feedstock ratio between 1 and 400 standard cubic meters/cubic meter. 6. The process according to any of the preceding claims, wherein the extraction step of the aromatics (D) comprises the following steps: extraction of the aromatics from the hydrogenation product (6) by means of a liquid-liquid extractor (T1) fed with a solvent stream (9) to separate the graphene (10) and extract (11) concentrated in aromatics with respect to the hydrogenation product composition (6); separation of the extract (11) by means of an extraction fractionation section (T3) to separate a gas stream (12) comprising non-aromatic compounds and the pure extract (13); separation of the aromatics from the pure extract (13) and the solvent by means of an aromatic recovery tower (T6) to separate the solvent stream (9) and the vapor at the top of the tower comprising the aromatic stream (17); 7. The process according to claim 6, wherein the step of aromatics extraction (D) further comprises at least one of the following steps: feeding the liquid-liquid extractor (T1) with a solvent stream (9) comprising a solvent selected from a list consisting of ethylene glycol, diethylene glycol, triethylene glycol, hexamethylphosphoramide, propylene carbonate, ethylene carbonate, sulfo lane, 3 methyl sulfo lane, N methyl acetamide, N,N dimethyl acetamide, butyrolactone, 1 methyl pyrrolidone, dimethyl dimethyl sulfoxide sidecaprolactam, N methyl formamide, pyrrolidine2 transferurfural, 1,1,3,3 tetramethyl urea, and mixtures thereof, and separating the gas phase stream (12) in a condenser-restoration apparatus (CD3) to separate The raffinate recycling stream (15) and aqueous phase (14), decontamination of the raffinate (10) with water by means of a water-fed decontamination tower (T2) route (7) to produce the non-aromatic stream (19) and the aqueous decontamination liquor (18), recovery of at least one portion of the solvent stream (9) by means of a solvent recovery section route by vacuum steam separation, condensation of the vapor at the top of the tower in a chiller condenser (CD6) to produce the aromatic stream (17). 8. The process of claim 7, wherein the solvent stream (9) comprises sulfolane. 9. The process according to claim 7, wherein the step of extracting the aromatics (D), further comprising at least the following steps: feeding the liquid-liquid extractor (T1) with a stream of solvent selected from ethylene glycol, diethylene glycol, triethylene glycol, hexamethylphosphoramide propylene carbonate, ethylene carbonate, sulfolane, 3 methyl sulfolane, N methyl acetamide, N, N di methyl acetamide, butyrolactone, 1 methyl pyrrolidone, dimethyl dimethyl sulfoxide capro lactam, N methyl formamide, pyrrolidine 2 transferrfural, 1,1,3,3 tetramethyl urea and mixtures thereof. Recycling of the obtained raffinate recycling stream (15) to the liquid-liquid extractor (T1), separating out the hydrocarbon compounds present in the liquor, removing impurities (18), acetic acid and/or in the aqueous phase (14) by means of a dewatering section to produce water, feeding the aromatic recovery tower (T6) with steam (8) to produce a vapor at the top of the tower further comprising steam, and condensing the vapor at the top of the tower in a resting condenser (CD6) to produce the aromatic stream (17) and water (16) separated by resting. 10. The process of claim 9, wherein the extraction step of the aromatics (D) further comprises at least one of the following steps: feeding the liquid-liquid extractor (T1) with a stream of solvent (9) comprising sulfolane and water, recycling the water produced by the dehydration section into an aromatics recovery tower (T6). 11. Apparatus for the conditioning and separation of aromatic compounds starting from a gasoline feedstock, comprising the following units: an optional hydrogenation unit (A) for the hydrogenation of at least the diolefins contained in the gasoline feedstock (1) in the presence of hydrogen (2) and for the optional production of the hydrogenation by-product (3); a fractional distillation unit (B) for the optional fractional distillation of the hydrogenation by-product (3) and the production of at least a fractional distillation range C5 (4) comprising compounds having 5 carbon atoms or less and a fractional distillation range C6+ (5) comprising compounds having at least 6 carbon atoms; a hydrogenation unit (C) for the hydrogenation of at least the olefins contained in the fractional distillation range C6+ (5) in the presence of hydrogen and the production of the hydrogenation by-product (6); an aromatic extraction unit (D) for the extraction of aromatics from compounds The hydrogenation-derived (6) and raffinate-derived (17) yields a minimum concentration of aromatic compounds relative to the hydrogenation-derived (6) and non-aromatic compounds relative to the composition of the hydrogenation-derived (6) yields a minimum concentration of aromatic compounds relative to the composition of the hydrogenation-derived (17) yields. 12. The apparatus of claim 11, wherein the aromatic extraction unit (D) comprises the following essential parts: a liquid-liquid extractor (T1) suitable for being fed with a stream of solvent (9) and hydrogenation product (6) and suitable for separating the raffinate (10) and extract (11) concentrated in aromatics with respect to the hydrogenation product composition (6), a desorption fractionation section (T3) suitable for being fed with the extract (11) and suitable for separating a gas stream (12) comprising non-aromatic compounds and the pure extract (13), and a recovery tower (T6) suitable for being fed with the pure extract (13) and suitable for separating the aromatics from the pure extract (13) to produce a stream of solvent (9) and a vapor at the top of the tower comprising an aromatic stream (17). 13. The apparatus of claim 12, wherein the unit for aromatic extraction (D) further comprising at least one of the following essential parts: a liquid-liquid extractor (T1) suitable for being fed with a stream of solvent (9), comprising a solvent selected from a list consisting of ethylene glycol, diethylene glycol, triethylene glycol, hexamethylphosphoramide propylene carbonate, ethylene carbonate, sulfolane, 3 methyl sulfolane, N methyl acetamide, N,N dimethyl acetamide, butyrolactone, 1 methyl pyrrolidone, dimethyl dimethyl sulfoxide caprolactam, N methyl formamide, pyrrolidine2 transferurfural, 1,1,3,3 tetramethyl urea and mixtures thereof. and a restoring condenser (CD3) suitable for being fed with a gas stream (12) and suitable for separating the gas stream (12) and the produced raffinate recycling stream (15) and the water phase (14); a water decontamination tower (T2) suitable for being fed with water (7) and raffinate (10) and suitable for decontaminating the raffinate (10) with water and the produced non-aromatic stream (19) and the decontaminated acquess slick (18); a solvent recovery section suitable for being fed with at least one fraction of the solvent stream (9) and suitable for recovering a fraction of the solvent stream (9) by vacuum steam separation; a restoring condenser (CD6) suitable for being fed with a vapor at the top of the tower and suitable for condensing the vapor at the top of the tower and suitable for producing the aromatic stream (17); 14. The apparatus of claim 13, wherein the unit for aromatic extraction (D) further comprising at least one of the following essential parts: a liquid-liquid extractor (T1) suitable for being fed with a stream of solvent (9), comprising a solvent selected from a list consisting of ethylene glycol, diethylene glycol, triethylene glycol, hexamethylphosphoramide propylene carbonate, ethylene carbonate, sulfolane, 3 methylsulfonyl, N methyl acetamide, N,N dimethyl acetamide, butyrolactone, 1 methyl pyrrolidone, dimethyl dimethyl sulfoxide caprolactam, N methyl formamide, pyrrolidine2 transferrfural, 1,1,3,3 tetramethylurea, and mixtures thereof. A suitable liquid-liquid extractor (T1) for being fed with a raffinate recycling stream (15), a suitable dehydration section for being fed with an aqueous deionized liquor (18) and/or aqueous phase (14) and for separating hydrocarbon compounds from the aqueous deionized liquor (18) and/or the aqueous phase (14) to produce water, an aromatic recovery tower (T6) suitable for being fed with steam (8) and suitable for producing a top-of-tower vapor further comprising steam, and a resting condenser (CD6) suitable for condensing the top-of-tower vapor to produce an aromatic stream (17) and water (16) separated by resting. 15. The apparatus of claim 14, wherein the unit for aromatic extraction (D) further comprises at least one of the following essential parts: a suitable liquid-liquid extractor (T1) fed with a stream of solvent (9) comprising aqueous sulfolane, an aromatic recovery tower (T6) suitable for being fed with water produced by the dehydration section;