RU2548040C1 - Oil refining method - Google Patents

Abstract

FIELD: oil-and-gas industry.

SUBSTANCE: method comprises the passing heated raw materials through heat exchangers and a furnace into a complex topping unit fitted with lateral stripping sections with supply to the bottom of sections and a complex topping unit of heated flows, withdrawal from the top of the complex topping unit of light petrol fraction and its supply after heating into a stabiliser tower with release of gas and stable light petrol fraction, side streams through stripping sections - heavy petrol, kerosene and diesel fractions and from the bottom of the complex topping unit of fuel oil, supply of fuel oil after heating in the furnace into the vacuum column with lateral withdrawal of diesel fraction, light vacuum gasoil using a circulating irrigation and from the bottom of the vacuum column - tar, using the circulating irrigation in the complex topping unit and supply of the heated flow into the bottom of the vacuum column, meanwhile the raw materials after heating in heat exchangers are separated into two flows, the flow, larger by quantity, is heated in the furnace and is supplied to the feeding zone of the complex topping unit, and smaller without heating is supplied between the supply of the bigger flow and withdrawal of diesel fraction, the complex topping unit contains two circulating irrigations, the heated flows are supplied to the bottom of stripping sections which are vapours after evaporation of light hydrocarbons from the residues of the stripping sections, into the bottom of the complex topping unit - heated gas from the stabilisation column where the reflux is selected, from the first plate of the vacuum column located above the supply of raw materials the heavy vacuum gasoil is withdrawn, it is used for heating of a part of diesel fraction of the vacuum column and supplied for mixing with fuel oil before its heating in the furnace, the diesel fraction heated by heavy vacuum gasoil is additionally heated in the furnace and supplied as a heated flow into the bottom of the vacuum column, lateral withdrawal of diesel fraction of the vacuum column is taken as a top circulating irrigation, and the light vacuum gasoil - as a lower one.

EFFECT: invention allows to lower energy consumption and to avoid formation of drains of acidic water, to increase withdrawal of vacuum gasoil and to decrease the level of decomposition of fuel oil in the furnace.

1 tbl, 1 dwg

Description

The invention relates to methods for the distillation of oil and can be used in the refining industry.

There is a known method of oil distillation, including heating and introducing raw materials into a distillation column with vapor supply from the top of the column after partial condensation into an irrigation tank to produce gas and a light gasoline fraction, gasoline and diesel fractions being separated by side straps through stripping sections, and fuel oil from the bottom, using acute and circulating irrigation and introducing heated streams into the column and stripping sections, further distillation of fuel oil in a vacuum column to obtain vacuum distillates and tar (I. A. Alexandrov. Perego ka and rectification in oil refining -.. M .: Chemistry, 1981, 148, III of rice -. 1b).

The disadvantage of this method is the high energy consumption.

The closest to the proposed invention in terms of technical nature and the achieved effect is a method of distillation of oil, which includes the introduction of heated raw materials into a complex atmospheric column equipped with side stripping sections with the supply of sections and a complex column of water vapor (heated streams), selection from the top of a complex atmospheric column light gasoline fraction and its supply after heating to the stabilization column with evolution of gas and light stable gasoline (stable light gasoline fraction), side shoulder straps through stripping sections - heavy gasoline (heavy gasoline fraction), kerosene (kerosene fraction) and light diesel fuel (diesel fraction) and from the bottom of a complex atmospheric fuel oil column, fuel oil supply after heating in an oven to a vacuum column with lateral selection of oil distillates (diesel fraction) , light vacuum gas oil using circulating irrigation and from the bottom of the vacuum column - tar, using circulating irrigation in complex atmospheric and vacuum columns and introducing water vapor (heated stream) into the bottom of the vacuum column nna (IA Alexandrov. Distillation and rectification in oil refining. - M.: Chemistry, 1981, p. 149, Fig. III - 2).

The disadvantage of this method is the high energy consumption, the formation of acid water effluents, the low selection of vacuum gas oil and a high degree of decomposition of fuel oil in the furnace.

The objective of the invention is to reduce energy consumption and avoid the formation of acid water effluents, as well as to increase the selection of vacuum gas oil and reduce the degree of decomposition of fuel oil in the furnace.

This problem is solved by the fact that in the method of distillation of oil, which includes the introduction of heated raw materials through heat exchangers and a furnace into a complex atmospheric column equipped with side stripping sections with heated sections supplied to the bottom of the section and a complex atmospheric column, selection of light gasoline fraction from the top of the complex atmospheric column and its supply after heating to the stabilization column with evolution of gas and a stable light gasoline fraction, side shoulder straps through stripping sections of heavy gasoline, kerosene and diesel fractions and from behind a complex atmospheric fuel oil column, supply of fuel oil after heating in a furnace to a vacuum column with side extraction of diesel fraction, light vacuum gas oil using circulating irrigation and from the bottom of the vacuum column - tar, using circulating irrigation in complex atmospheric and vacuum columns and introducing a heated stream to the bottom of the vacuum column, according to the invention, the raw material after heating in heat exchangers is divided into two streams, the larger amount is heated in the furnace and fed into the feed zone of a complex atmospheric column while the smaller one is fed without heating between the input of a larger stream and the output of the diesel fraction, a complex atmospheric column contains two circulation irrigation, steam is fed to the bottom of the stripping sections as heated streams after evaporation of light hydrocarbons from the remnants of the stripping sections, to the bottom of a complex atmospheric column - heated gas from the stabilization column, from which reflux is selected, from the first plate of the vacuum column located above the input of raw materials, heavy vacuum gas oil is removed, part of the diesel oil is heated by it fractions of the vacuum column and fed to the fuel oil before heating it in the furnace, the diesel fraction heated by heavy vacuum gas oil is additionally heated in the furnace and introduced as a heated stream to the bottom of the vacuum column, the lateral selection of the diesel fraction of the vacuum column is withdrawn as upper circulation irrigation, and light vacuum gas oil - as the bottom.

The figure shows a diagram of the implementation of the proposed method.

The raw materials are heated in heat exchanger 1 and divided into two streams, the greater amount of stream 2 is heated in the furnace 3 and introduced via line 4 into the feed zone of column 5, a smaller stream 6 is also introduced into column 5 above the input of a larger quantity of raw material stream. Vapors from the top of the column 5 are partially condensed in the condenser-cooler 7 and introduced via line 8 into the irrigation tank 9. Hydrocarbon gas is discharged from the top of the irrigation tank 9 through line 10. From the bottom of the tank irrigation 9 drain fluid. Part of the liquid along line 11 is fed to the top of column 5, and the balance excess is withdrawn along line 12 as a light gasoline fraction. The upper side stream of column 5 along line 13 is fed to the top of the upper stripping section 14. Vapors from the top of stripping section 14 along line 15 are returned to the column 5. From the bottom of the stripping section 14, liquid is withdrawn from line 16 and fed to the evaporator 17. Vapors from the evaporator 17 line 18 is returned to the bottom of the stripping section 14. From the bottom of the evaporator 17, line 19 removes the heavy gasoline fraction. The upper circulation irrigation of the column 5 is cooled in the heat exchanger 20 and returned to line 5 through line 21. The average lateral overhead of column 5 along line 22 is fed to the top of the middle stripping section 23. Vapors from the top of the stripping section 23 along line 24 are returned to the column 5. From the bottom liquid stripping section 23 is withdrawn from line 25 and fed to evaporator 26. Vapors from evaporator 26 via line 27 are returned to the bottom of stripping section 23. From the bottom of evaporator 26, kerosene fraction is withdrawn from line 28. The lower side stream of the column 5 via line 29 is fed to the top of the lower stripping section 30. Vapors from the top of the stripping section 30 along line 31 are returned to the column 5. From the bottom of the stripping section 30, liquid is removed through line 32 and fed to the evaporator 33. Vapors from the evaporator 33 on line 34 return to the bottom of stripping section 30. From the bottom of the evaporator 33 on line 35 divert the diesel fraction. The lower circulation irrigation of column 5 is cooled in a heat exchanger 36 and returned to line 5 through line 37. The light gasoline fraction of column 5 is heated in heat exchanger 38 and fed to stabilization column 40 through line 39. Vapors from the top of stabilization column 40 are partially condensed in a condenser-cooler 41 and, through line 42, they are introduced into the irrigation tank 43. Gas is discharged from the top of the irrigation tank 43 through the line 44, heated in the heat exchanger 45, and liquid is sent to the bottom of the column 5 through the line 46. Part of the liquid along line 47 is fed to the top of the stabilization column 40, and the balance excess is withdrawn along line 48 as reflux. From the bottom of the stabilization column 40, liquid is withdrawn through line 49 and fed to the evaporator 50. Vapors from the evaporator 50 via line 51 are returned to the bottom of the stabilization column 40. A stable light gasoline fraction is withdrawn from the bottom of the evaporator 50 via line 52. The raw materials of the vacuum column 54 heated in the furnace 53 are fed via line 55 to the vacuum column 54. Non-condensable vapor is removed from the top of the vacuum column 54 via line 56. Liquid is withdrawn from column 54 through line 57, cooled in heat exchanger 58, and through line 59 it is fed to the top of column 54 as top circulation irrigation, and the balance excess is withdrawn through line 60 as the diesel fraction of the vacuum column 54. From column 54, along line 61 the liquid is cooled in the heat exchanger 62 and through line 63 is returned to the column 54 as a bottom circulating irrigation, and the balance excess through line 64 is removed as a light vacuum gas oil. A heavy vacuum gas oil is withdrawn from column 54 through line 65, cooled in a heat exchanger 66, and fed to line 67 with fuel oil discharged from column 5 via line 68 before being fed to furnace 53. Part of the liquid discharged through line 57 from column 54 , through line 69 it is fed to a heat exchanger 66, where it is heated, then through line 70 it is fed to the convection section of the furnace 53, and then through line 71 it is fed to the bottom of the column 54 as a heated stream. Tar is withdrawn from the bottom of column 54 along line 72.

Comparative characteristics of the main performance indicators of the columns according to the prototype and the proposed method, are shown in table 1, showed that the exclusion of the use of water vapor for stripping light fractions from the column separation products in the proposed method avoids the formation of acid water effluents on the oil distillation unit. This saves 2.7 t / h of water vapor. In addition, in the proposed method increases the selection of total vacuum gas oil from 46.50 to 51.70 t / h, that is, 11.2%. The amount of tar is reduced to 67.65 to 62.13 t / h, that is, by 8.2% and it is heavier. The temperature of the raw material at the entrance to the vacuum column is reduced from 370 to 365 ° C, which reduces the degree of decomposition of fuel oil in the furnace. The thermal load of condensers-refrigerators of a complex atmospheric column 5, due to the exclusion of the introduction of water vapor into it and the introduction of an unheated oil stream into the column 5, decreases from 6.659 to 3.672 Gcal / h, i.e. by 44.9%. By reducing the supply of heat with raw materials, the thermal load of the furnace of a complex atmospheric column 5 is reduced from 15.762 to 13.585 Gcal / h, that is, 13.8%, and the total load of furnaces of a complex atmospheric 5 and vacuum 54 column is reduced from 20.578 to 18.854 Gcal / h .

Thus, the present invention allows to reduce energy consumption and avoid the formation of acid water effluents, as well as to increase the selection of vacuum gas oil and reduce the degree of decomposition of fuel oil in the furnace.

Table 1 Key performance indicators of the columns Indicators Option 1 (prototype) Option 2 (the proposed method) one 2 3 Consumption, t / h top flow of raw materials 6 columns 5 - 29.00 lower flow of raw materials 2 columns 5 210.00 181.00 gas (stream 44) - 0.20 reflux (stream 48) 0.09 0,03 stable light gasoline fraction NK-100 ° C (stream 52) 8.31 8.37 heavy gasoline fraction 100-160 ° C (stream 19) 20.00 20.00 kerosene fraction 160-235 ° C (stream 28) 9.50 9.50 diesel fraction 235-360 ° C from column 5 (stream 35) 45.00 45.00 fuel oil (stream 68) 127.10 127.10 diesel fraction 235-360 ° C from column 54 (stream 60) 12.50 12.47 total diesel fraction (streams 35 + 60) 57.50 57.47 light vacuum gas oil from column 54 (stream 64) 20.00 51.70 heavy vacuum gas oil from column 54 (stream 65) 26,50 3.00 tar (stream 72) 67.65 62.13 total vacuum gas oil from the installation 46.50 51.70 vapors from the top of the column 5 58.50 35.03 acute column irrigation 5 (stream 11) 48.48 26.43 light gasoline fraction of column 5 (stream 12) 8.40 8.60 the upper side shoulder strap in stripping section 14 (stream 13) 22.72 25.19 vapor from the top of the stripping section 14 (stream 15) 2.92 5.19 the average side stream in stripping section 23 (stream 22) 12.49 11.29 vapor from the top of the stripping section 23 (stream 24) 3.28 1.79 bottom side strap in stripping section 30 (stream 29) 49.24 49.65 vapor from the top of the stripping section 30 (stream 31) 4.43 4.65 the upper CO column 5 (stream 21) 50.00 50.00 lower CO column 5 (stream 37) 150.00 150.00 vapor from the top of the column 54 (stream 56) 1.55 0.90 non-condensable vapor column 54 0.91 0.73 suction 0.10 0.10 condensate columns 54 0.64 0.17 water condensate columns 54 0.47 - top CO columns 54 (stream 59) 55.00 90.00 bottom CH columns 54 (stream 63) 90.00 190.00 heavy vacuum gas oil (darkened product) into the furnace (stream 67) - 3.00 vaporizing agent to column 54 (stream 71) 1,0 3.00 water vapor:

Continuation of table 1

to column 5 1.00 - in stripping section 14 0.20 - in stripping section 23 0.30 - in stripping section 30 0.20 - vapors from the top of the column 40 2.16 2.88 acute column irrigation 40 (stream 47) 2.07 2.65 liquid from the bottom of the column 40 (stream 49) 14.39 14.37 vapor to the bottom of the column 40 (stream 51) 6.08 6.00 vapor at the bottom of stripping section 14 (stream 18) - 5.45 vapor at the bottom of stripping section 23 (stream 27) - 2.59 vapor at the bottom of stripping section 30 (stream 34) - 10.79 gas to the bottom of column 5 (stream 46) - 0.20 Temperature ° C top flow of raw materials 6 columns 5 245 245 lower flow of raw materials 2 columns 5 350 350 input acute irrigation columns 5 (stream 11) and 40 (stream 47) 40 40 and 50 top of column 5 87 92 the output of the upper side stream (stream 13) in the stripping section 14 117 119 the output of the average side stream (stream 22) in the stripping section 23 183 183 output lower side shoulder strap (stream 29) in stripping section 30 243 238 output top CH columns 5 145 147 input upper CO columns 5 (stream 21) 55 55 output lower CO columns 5 243 238 input lower CO columns 5 (stream 37) 170 170 bottom of column 5 342 346 top of stripping section 14 113 119 bottom of stripping section 14 103 121 in the boiler 17 of the stripping section 14 - 126 top stripping section 23 173 185 bottom of stripping section 23 158 193 in the boiler 26 of the stripping section 23 - 200 top stripping section 30 241 240 bottom of stripping section 30 236 252 in the boiler 33 stripping section 30 - 269 top of column 54 76 76 the output of the diesel fraction 235-360 ° C from the column 54 (stream 57) 149 123 input upper CO columns 54 (stream 59) fifty fifty after heat exchangers raw materials columns 5 245 245 after heat exchangers of the evaporating agent (stream 70) of the column 54 - 335 withdrawal of vacuum gas oil from column 54 (stream 61) 246 256 input lower CO columns 54 (stream 63) 200 200 withdrawal of heavy vacuum gas oil (darkened product) from the column 54 (stream 65) 320 365

input raw materials (stream 55) in the column 54 370 365 the input of the heated stream (stream 71) in the column 54 350 370 introducing water vapor into the column 54 350 - bottom of column 54 362 364 top of column 40 62 64 input raw materials (stream 39) in the column 40 128 127 bottom of the column 40 159 152 in a boiler 50 columns 40 161 154 Pressure, ata (mmHg) in the tank irrigation columns 5 1.10 1.10 top of column 5 1,60 1,60 bottom of column 5 1.90 1.90 top of stripping section 14 1.85 1.85 bottom of stripping section 14 1.89 1.89 top stripping section 23 1.97 1.97 bottom of stripping section 23 1.98 1.98 top stripping section 30 2.03 2.03 bottom of stripping section 30 2.04 2.04 top of column 54 (68) (twenty) in the feed zone of the column 54 (80) (32) bottom of column 54 (one hundred) (52) in the column irrigation tank 40 7.5 6.5 top of column 40 8.0 7.0 bottom of the column 40 8.2 7.2 Thermal load, Gcal / h heat supplied to the bottom of the stripping section 14 - 0.436 heat supplied to the bottom of the stripping section 23 - 0.217 heat supplied to the bottom of the stripping section 30 - 1,214 condenser-coolers 7 columns 5 6,659 3,672 heat exchangers 1 columns 5 25,513 25,513 heat exchangers 20 of the upper central column 5 2,485 2,549 heat exchangers 36 lower CH columns 5 6,888 6,337 in front of the oven 3 columns 5 27,709 27,709 ovens 3 columns 5 15,762 13,585 furnaces 53 columns 54 4,816 5,269 heat exchangers 66 for heating a heated column stream 54 - 0.408 heat exchangers 58 of the upper CH columns 54 2,807 3,336 heat exchangers 62 lower CH columns 54 4,432 6,532 furnaces 53 for heating the heated column stream 54 - 0.212 heat exchangers 38 raw material columns 40 0.431 0.442 condenser coolers 41 columns 40 0.192 0.225 boiler 50 columns 40 0.375 0.380 The number of theoretical plates, pcs. in 1 section of the column 5 four four in 2 sections of column 5 2 2 in 3 sections of column 5 6 6 in 4 sections of column 5 one one in section 5 of column 5 2 2 in 6 sections of column 5 2 2 in section 7 of column 5 2 2

in the 8 distant section of the column 5 2 2 in column 54 fourteen fourteen in stripping section 14 four four in stripping sections 23 and 30 3 3 in column 40 10 10 Diameter m columns 5 3.4 3.0 stripping section 14 1,0 1,2 stripping section 23 0.8 0.8 stripping section 30 1,2 1,2 columns 40 1,0 1,0 columns 54 3.8 4.2 The distance between the plates, mm (threading) in column 5 500 (1-3) 500 (1-3) in stripping section 14 400 (1) 500 (1) in stripping section 23 400 (1) 500 (1) in stripping section 30 400 (1) 500 (1) in column 40 400 (1) 500 (1) Temperature 5-95% vol. boiling according to GOST stable light gasoline fraction NK-100 ° C (stream 52) 70-98 70-98 heavy gasoline fraction 100-160 ° C (stream 19) 98-154 98-158 kerosene fraction 160-235 ° C (stream 28) 166-216 162-224 diesel fraction 235-360 ° C from column 5 (stream 35) 214-338 213-359 fuel oil (stream 68) 322-637 294-636 diesel fraction 235-360 ° C from column 54 (stream 60) 252-365 229-338 total fraction 235-360 ° C 218-348 216-352 total vacuum gas oil from the installation 356-503 365-540 tar (stream 72) 482-651 505-652

Claims (1)

A method of distillation of oil, including the introduction of heated raw materials through heat exchangers and a furnace into a complex atmospheric column equipped with lateral stripping sections with the supply of sections and a complex atmospheric column of heated streams to the bottom, the selection of light gasoline fraction from the top of the complex atmospheric column and its supply after heating to the stabilization column with gas evolution and stable light gasoline fraction, side shoulder straps through stripping sections - heavy gasoline, kerosene and diesel fractions and fuel oil from the bottom of a complex atmospheric column feeding fuel oil after heating in the furnace into a vacuum column with lateral extraction of diesel fraction, light vacuum gas oil using circulating irrigation and from the bottom of the vacuum column - tar, using circulating irrigation in a complex atmospheric column and introducing a heated stream into the bottom of the vacuum column, characterized in that the raw materials after heating in the heat exchangers are divided into two streams, the larger stream is heated in the furnace and fed into the feed zone of a complex atmospheric column, and the smaller one is fed more between the input without heating of the flow and the output of the diesel fraction, the complex atmospheric column contains two circulating irrigation, vapor is supplied to the bottom of the stripping sections as heated streams after evaporation of light hydrocarbons from the remnants of the stripping sections, to the bottom of a complex atmospheric column is heated gas from the stabilization column from which reflux, from the first plate of the vacuum column located above the input of the raw materials, the heavy vacuum gas oil is removed, a part of the diesel fraction of the vacuum column is heated with it, and mixed with fuel oil before agrevom in an oven heated heavy vacuum gas oil diesel fraction is further heated in a furnace and injected as the heated stream to the bottom of the vacuum column, side withdrawal diesel fraction vacuum column is output as the upper pumparound and light vacuum gas oil - as the bottom.

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