초록 ▼

Two-stage low pressure catalytic hydrotreatment of heavy petroleum hydrocarbons having a high content of contaminants (metals and asphaltenes), is conducted under operating conditions with low-pressure, in a fixed bed or ebullated bed reactor to limit the formation of sediments and sludge in the pro

Two-stage low pressure catalytic hydrotreatment of heavy petroleum hydrocarbons having a high content of contaminants (metals and asphaltenes), is conducted under operating conditions with low-pressure, in a fixed bed or ebullated bed reactor to limit the formation of sediments and sludge in the product and obtain a hydrotreated hydrocarbon of improved properties, with levels of contaminants, API gravity and distillates within the ranges commonly reported in the feedstocks typical to refining schemes. A hydrotreatment catalyst, whose principal effect is the hydrodemetallization and the hydrocracking of asphaltenes of the heavy hydrocarbons of petroleum is used in the first stage, and the second reaction stage employs a hydrotreatment catalyst for a deeper effect of hydrodesulfurization of the heavy petroleum hydrocarbon whose content of total sulfur is reduced to a level required for its treatment in the conventional refining process or for its sale as a hydrocarbon of petroleum with improved properties.

대표청구항 ▼

Having described the present invention, it is considered as an innovation and therefore, the contents of the following clauses are claimed as property: 1. A two-stage low pressure reaction process for the catalytic hydrotreatment of heavy petroleum hydrocarbons containing a high content of metals,

Having described the present invention, it is considered as an innovation and therefore, the contents of the following clauses are claimed as property: 1. A two-stage low pressure reaction process for the catalytic hydrotreatment of heavy petroleum hydrocarbons containing a high content of metals, total sulfur, asphaltenes and total nitrogen to improve the properties of the feed hydrocarbons, limit the formation of sediment and sludge, and attain a high removal of contaminants, said process comprising subjecting said heavy petroleum hydrocarbon feedstock to a first reaction stage with hydrogen and a catalyst comprising nickel-molybdenum-titania on gamma alumina and a second reaction stage with hydrogen and a catalyst comprising cobalt-molybdenum-titania on gamma alumina, wherein each of said stages is conducted at a pressure of 40 to 130 kg/cm2, a temperature of 320° to 450° C., a space velocity (LHSV) of 0.2 to 3.0 h−1, and a hydrogen/hydrocarbon ratio (H2/HC) of 350 to 1,200 nl/l. 2. The two-stage reaction process of claim 1, wherein hydrodemetallization of hydrocarbons and hydrocracking of asphaltenes is conducted in said first stage. 3. The two-stage reaction process of claim 2, wherein hydrodesulfurization and hydrodenitrogenation of hydrocarbons is conducted in said second stage. 4. The two-stage reaction process of claim 3, wherein the first reaction stage is conducted at a pressure of 45 to 90 kg/cm−2, a temperature of 350° to 450° C., a space velocity (LHSV) of 0.2 to 2.0 h−1, and a hydrogen/hydrocarbon ratio (H2/HC) of 450 to 1,050 nl/l. 5. The two-stage reaction process of claim 4, wherein the second reaction stage is conducted at a pressure of 45 to 90 kg/cm2, a temperature of 330° to 450° C., a space velocity (LHSV) of 0.2 to 2.0 h−1, and a hydrogen/hydrocarbon ratio (H2/HC) of 450 to 1,050 nl/l. 6. The two-stage reaction process of claim 5, wherein said process minimizes the formation of sediment and sludge to a maximum value of 0.65% by weight of the hydrotreated hydrocarbon. 7. The two-stage reaction process of claim 5, wherein said heavy hydrocarbon feed comprises less than 80% by volume of distillates recovered @538° C. and an API gravity below 32°. 8. The two-stage reaction process of claim 7, wherein conversion values of up to 70% by volume of the feed stock are obtained. 9. The two-stage reaction process of claim 5, wherein the properties of the product compared with the feedstock comprise an increase in API gravity up to approximately 15 units and in the content of distillates recovered @538° C. up to approximately 50% by volume, as compared with the feed. 10. The process of claim 1, wherein each said reaction stage is conducted in a fixed-bed reactor or ebullated-bed reactor. 11. The process of claim 10, wherein each of said reaction stages is conducted in a fixed bed reactor. 12. The process of claim 11, wherein said process minimizes the formation of sediment and sludge to a maximum value of 0.8% by weight of the hydrotreated hydrocarbon. 13. The process of claim 12, wherein said process minimizes the formation of sediment and sludge to a maximum value of 0.65% by weight of the hydrotreated hydrocarbon. 14. The process of claim 10, wherein each said reaction stage contains a hydrotreatment catalyst. 15. The process of claim 10, wherein each reaction stage is conducted in an ebullated bed reactor. 16. The two-stage reaction process of claim 1, wherein the amount of sediment and sludge formed in each of said first and second reaction stages is less than 0.65% by weight of the hydrotreated hydrocarbon. 17. The process of claim 1, wherein the weight % titania in the first reaction stage catalyst exceeds the weight % nickel in said first reaction stage catalyst. 18. The process of claim 17, wherein the weight % titania in the second reaction stage catalyst exceeds the weight % cobalt in said second reaction stage catalyst. 19. A two-stage reaction process for the catalytic hydrotreatment of heavy petroleum hydrocarbons containing a high content of metals, total sulfur, asphaltenes and total nitrogen, which process comprises a) passing hydrogen and a heavy petroleum hydrocarbon feedstock having a specific gravity less than 32° API and a content of distillates recovered @538° C. less than 80% by volume to a first reaction stage for hydrotreatment of said feedstock, said first reaction stage comprising a fixed bed or ebullated bed reactor containing a nickel-molybdenum-titania catalyst on a gamma-alumina support and operated to provide a pressure of 40 to 130 kg/cm2, a temperature of 320° to 450° C., a space velocity (LHSV) of 0.2 to 3.0 h−1, and a hydrogen/hydrocarbon ratio (H2/HC) of 350 to 1,200 nl/l, so to form a hydrotreated heavy hydrocarbon, b) passing hydrogen and said hydrotreated heavy hydrocarbon to a second reaction stage in a fixed bed or ebullated bed reactor containing a cobalt-molybdenum-titania catalyst on a gamma-alumina support for hydrotreatment at a pressure of 40 to 130 kg/cm2, a temperature of 320° to 450° C., space velocity (LHSV) of 0.2 to 3.0 h−1, and a hydrogen/hydrocarbon ratio (H2/HC) of 350 to 1,200 nl/l, wherein the amount of sediment and sludge formed in each of said first and second reaction stages is less than 0.8% by weight of the hydrotreated hydrocarbon. 20. The two-stage reaction process of claim 19, wherein the amount of sediment and sludge formed in each of said first and second reaction stages is less than 0.65% by weight of the hydrotreated hydrocarbon. 21. The process of claim 19, wherein the weight % titania in the first reaction stage catalyst exceeds the weight % nickel in said first reaction stage catalyst. 22. The process of claim 21, wherein the weight % titania in the second reaction stage catalyst exceeds the weight % cobalt said second reaction stage catalyst.