RU2021124374A - Method for adjusting the sulfur content in the fuel - Google Patents

Claims (36)

1. A method for adjusting the sulfur content of a fuel containing components derived from the processing of crude oil, in which the sulfur content of the fuel for a ship is corrected to less than the maximum applicable IMO specification for sulfur at the point of burning the above fuel by the above ship to reduce sulfur emissions in in accordance with IMO specifications whether at sea, on return from sailing and when leaving the sea within the environmental control zone, or docked in the port to generate electricity on board the ship to supply the port electricity, while the above-mentioned fuel differs in that that the aforementioned fuel has an actual sulfur content of 0.50% by mass (wt.%) or less and contains a number of hydrocarbons derived from crude oil from C3 or C5 to fractions exceeding C20, while the aforementioned hydrocarbons have an initial boiling point , which is the lowest boiling point of any fr shares in the streams combined in the above fuel that have not been treated with hydrogen, and the highest boiling point is the highest boiling point of the soluble component in the stream treated with hydrogen and combined in the above fuel. 2. The method according to claim 1, in which the aforementioned corrected fuel meets or exceeds all the specifications of ISO RMA 10 (ISO 2817-10), except for the flash point, characterized in that such fuel contains a number of hydrocarbons having an initial boiling point naphtha, and the highest boiling point is the highest boiling point of its component soluble in a solvent suitable for separating the solvent, while the above fuel contains: (a) sulfur 0.50% by mass (wt%) or less, (b) sodium maximum 10 mg/kg, vanadium maximum 0.2 mg/kg and aluminum and silicon maximum 0.2 mg/kg, (c) flash point less than 60ºC without flash point adjustment. 3. The method according to p. 1, characterized in that the aforementioned fuel has one or more additional distinctive characteristics: (a) viscosity less than 10 cSt, (b) a pour point of 0 (zero) ºC or less, (c) density at 15ºC in the range of 820 to 880 kg/m ³ and (d) CCAI less than 800. 4. The method of claim 1, wherein the combustion of said fuel falls under the SOLAS exemption for flash point requirements for cargo ships, or which comprises adjusting the flash point to a flash point of 60ºC or higher. 5. The method according to claim 1, characterized in that the above fuel contains the majority of the entire range of hydrocarbons derived from crude oil, from fractions C3 or C5 to fractions exceeding C20, while the above hydrocarbons have an initial boiling point that is the lowest the boiling point of any fraction of the above crude oil under atmospheric distillation conditions, and the highest boiling point is the highest boiling point of a component of any fraction of the above crude oil under atmospheric distillation conditions, which is soluble in a solvent suitable for separating the solvent. 6. The method according to p. 1, characterized in that the aforementioned fuel contains (a) hydrotreated liquids streams above the sulfur break point, and (b) crude liquid fractions at or below the sulfur breakpoint, and said fuel does not contain an oil residue insoluble in one or more solvents used to separate the solvent. 7. The process of claim 1, wherein said fuel comprises an ultra-low sulfur hydrotreated stream having 10 parts per million by weight or less of sulfur. 8. The method of claim 1, wherein said fuel contains a combination of hydrocarbons ranging from the lowest boiling point portion of the aforementioned crude liquid fraction to the highest boiling point portion of solubles that results from the separation of the solvent. 9. The method of claim 1, wherein said fuel comprises an ultra-low sulfur stream having 10 parts per million by weight or less of sulfur. 10. The method of claim 1, wherein said fuel contains a combination of hydrocarbons ranging from the lowest boiling point portion of the aforementioned crude liquid fraction to the highest boiling point portion of solubles resulting from the separation of the solvent. 11. The process of claim 1, wherein said fuel comprises a first hydrotreated stream that is a reduced sulfur stream having a sulfur content of less than 10 ppm by weight of sulfur, and the second hydrotreated fuel stream is a reduced sulfur stream. sulfur content, having a sulfur content in the range from 0.12 to 0.18 wt. % sulfur, and the crude fraction has a sulfur content above, at or below the target sulfur content. 12. The process of claim 1 wherein said fuel has a target sulfur content in accordance with the IMO marine fuel specification and the crude fraction has a sulfur content above, at or below the target sulfur content. 13. The method of claim 1 wherein said fuel comprises tight reservoir light oil or condensate or a combination of tight reservoir light oil and condensate from one or more crude fractions, hydrotreated streams, and when the flash point of the fuel is not considered, said tight reservoir light oil has a sulfur content in the range from 0.1 wt. % to 0.2 wt. % and density, API (deg.), in the range from 38 to 57, and the ranges of fractions of the distillate cut, in wt.%, (a) from 5 to 20 wt. % range of liquefied hydrocarbon gas, (b) from 10 to 35 wt. % naphtha, (c) 15 to 30 wt. % kerosene, (d) 15 to 25% diesel fuel, (e) vacuum gas oils, and (f) zero (0%) to 10% heavy oil residues. 14. The method of claim. 1, characterized in that the above fuel contains hydrocarbons having an initial boiling point in the range from about 35ºC to about 315ºC and above up to a maximum boiling point, which is the initial boiling point of deasphalted oil at the end of the cycle in the above fuel and deasphalted oil residue at the beginning of the cycle, which is not soluble in the solvent selected for the separation of the solvent, and is not in the aforementioned fuel. 15. The method of claim. 1, characterized in that the above fuel contains a combination of hydrocarbons in the range from a portion of the crude liquid fraction with the lowest boiling point, which is obtained as a result of atmospheric distillation, at or below the breakpoint of the sulfur content to a portion of hydrotreated solutes with the highest boiling point, which is obtained as a result of the separation of the solvent liquid fractions above the break point of the sulfur content. 16. The method of claim 1, wherein said fuel has an initial boiling point which is the lowest boiling point of any fraction in the raw streams in said fuel, and the highest boiling point is the highest boiling point of the effluent stream that is obtained as a result of separation of the solvent treated with hydrogen, and forms a portion of the aforementioned fuel. 17. The method according to p. 1, characterized in that the aforementioned fuel contains (a) unrefined, unstabilized straight-run naphtha and other atmospheric distillation cut below or at the break point sulfur content cut, (b) a hydrotreated distillate effluent containing unstabilized naphtha and all or a portion of the low sulfur diesel fuel, and (c) hydrotreated oils containing hydrotreated diesel fuel and hydrotreated oil heavier than diesel fuel having the highest boiling point, which is the highest boiling point of the purified effluent portion that results from solvent separation. 18. The method of claim. 1, characterized in that the aforementioned fuel has an actual sulfur content corresponding to the limit level of the target sulfur content or below it, containing at least three components, each of which has a different sulfur content, while the actual sulfur content in the aforementioned fuel is characterized by the respective sulfur content of the crude component at or below the sulfur content breakpoint and the two refined components above the sulfur content breakpoint up to the highest boiling point, which is the highest boiling point of the cleaned effluent portion that results from solvent compartments. 19. The process of claim 1, wherein said fuel has an actual sulfur limit characterized by increased or decreased amounts of hydrotreated distillate or hydrotreated heavy fuel relative to the reference sulfur content. 20. The method of claim. 1, characterized in that the aforementioned fuel has a limit level of the actual sulfur content, characterized by increased or decreased amounts of oil feedstock for distillation, distillate hydrotreating or heavy fuel oil or solvent separation with respect to reference to the end of the distillation cycle with sulfur content at the point a break or the beginning of a cycle of exponential rate of increase in the excess of sulfur content per unit volume. 21. The method of claim. 1, characterized in that the aforementioned fuel has a limit level of the actual sulfur content, characterized by components having a sulfur content in excess of the target sulfur limit of the treated fuel oil with a high sulfur content or less, or other heavy oil residue having a sulfur content above or below the target sulfur limit, increased or decreased amounts for distillation, distillate or heavy fuel hydrotreatment, or solvent separation with respect to reference to the end of the distillation cycle with sulfur content at the break point or the start of the cycle of exponential rise rate of excess content sulfur per unit volume. 22. The method of claim 1, wherein said fuel has an actual sulfur limit, characterized by components having a sulfur content greater than or less than the target sulfur limit of tight reservoir light oil or condensate or a combination of tight reservoir light oil or condensate or process light oil from low-permeability reservoirs or increased or reduced amounts of condensate for distillation, distillate or heavy fuel hydrotreatment, or solvent separation, with respect to reference to the end of the distillation cycle with sulfur content at the break point or the beginning of the cycle of exponential rise rate of excess sulfur content per unit volume. 23. The method of claim. 1, characterized in that the sulfur content of each raw component of the fuel has an actual sulfur content below or at the break point and each other component is a purified component, and the aforementioned fuel does not exceed the target sulfur content established by the maximum applicable specification IMO.