RU2790002C1 - Gas refining plant - Google Patents

Abstract

FIELD: cryogenic engineering.

SUBSTANCE: invention relates to cryogenic engineering and may be used in gas industry for processing hydrocarbon gases. A gas refining plant and a C₂₊ hydrocarbon separation unit, which includes a compressor section of a first detander-compressor unit, a main multi-stream heat exchanger, a separator equipped with separation gas and residue separation outlet lines on a purified and dried gas line, are proposed. The separation gas outlet line is divided into first and second separation gas supply lines, the separation residue outlet line is divided into first and second separation residue supply lines, the first separation residue supply line is connected to the first separation gas supply line with an upper multi-flow heat exchanger, a reducing valve and connected to the top of the rectification column, the second separation residue supply line is equipped with a reducing valve and connected to the middle part of the distillation column, the second separation residue supply line is fitted with a reduction valve and connected to the distillation column middle section, the second separation gas supply line is fitted with the first detander-compressor unit detander section and connected to the distillation column middle section above the second separation residue supply line. The top of the distillation column is fitted with a residue gas outlet line, on which the upper heat exchanger, the main heat exchanger, the connection with the second circulating gas branch after the compressor section of the second detander, the compressor unit, the chilling machine, the first circulating gas branch and the second circulating gas branch are successively arranged. The first circulation gas branch is equipped with a main heat exchanger, an upper heat exchanger and a reduction valve and connected to the top of the distillation column above the first separation gas supply line, the second circulation gas branch is equipped with the detander section of the second detander-compressor unit, upper heat exchanger, main heat exchanger, compressor section of the second detander-compressor unit and connected to the residual gas outlet line before the compressor unit. The bottom of the distillation column is connected to the main heat exchanger by the inlet/outlet lines of the first and second circulation sprinklers, and the bottom of the distillation column is connected to the main heat exchanger by the C₂₊ hydrocarbon fraction outlet line. A separator connected to the distillation column by a supply line for a second separation gas before the distillation column and to the outlet line for a third separation residue, and also a separator connected to the distillation column by a supply line for a fourth separation residue, and to the outlet line for a fourth separation residue before the distillation column is installed in the first separation gas supply line.

EFFECT: invention provides for increase the C₂₊ hydrocarbon fraction extraction degree and reduce diameter of upper part of distillation column.

5 cl, 1 dwg, 1 ex

Description

The invention relates to cryogenic technology and can be used in the gas industry for the processing of hydrocarbon gases.

Closest to the proposed invention is a method of refrigeration in a plant for extracting gas condensate liquids [RU 2763101, publ. 12/27/2021, IPC C10L 3/10, f25J 3/06], carried out at the installation for the separation of the hydrocarbon fraction С ₂₊ , including located on the lines of purified and dried gas: the compressor section of the first expander-compressor unit, the main multi-flow heat exchanger, separator , equipped with separation gas and separation residue outlet lines, wherein the separation gas outlet line is divided into the first and second separation gas supply lines, the separation residue outlet line is divided into the first and second separation residue supply lines, while the first separation residue supply line is connected to the supply line of the first separation gas, equipped with an upper multi-flow heat exchanger, a reducing valve, and connected to the upper part of the distillation column; co united with the middle part of the distillation column above the supply line of the second separation residue, in addition, the top of the distillation column is equipped with a residual gas outlet line, on which the upper heat exchanger, the main heat exchanger, the adjoining branch of the second circulation gas after the compressor section of the second expander-compressor unit, the compressor , a refrigerator, a branch of the first circulating gas and a branch of the second circulating gas, wherein the branch of the first circulating gas is equipped with a main heat exchanger, an upper heat exchanger and a reducing valve and is connected to the upper part of the distillation column above the supply line of the first separation gas, the branch of the second circulating gas is equipped with an expander section of the second expander -compressor unit, the upper heat exchanger, the main heat exchanger, the compressor section of the second expander-compressor unit and is connected to the residual gas outlet line before the compressor, in addition, the lower part of the distillation column is connected to the main heat exchanger by input/output lines of the first and second circulating irrigation, and the bottom of the distillation column is connected to the main heat exchanger by the output line of the hydrocarbon fraction C ₂₊ .

The disadvantages of this method and installation are the low degree of extraction of the C ₂₊ hydrocarbon fraction and the large diameter of the upper part of the distillation column, which, at high feed gas costs, requires the separation of the column into two parts due to its large weight. The reason for these shortcomings is the direct connection to the distillation column of the supply line of the second separation gas, which after reduction consists of more than 99% of the gas phase. This leads to a high load on the upper part of the column in the gas phase, which requires an increase in its diameter to prevent entrainment of the liquid phase, and also leads to losses of ethane with residual gas due to transfer to the gas phase enriched in methane from the liquid phase as a result of mass transfer.

The objective of the invention is to increase the degree of extraction of the fraction of hydrocarbons WITH ₂₊ and reduce the diameter of the upper part of the distillation column.

The technical result - increasing the degree of extraction of the C ₂₊ hydrocarbon fraction and reducing the diameter of the upper part of the distillation column - is achieved by installing at least one separator on the streams supplied to the upper part of the distillation column.

The claimed technical result is achieved by the fact that in a gas processing plant, including a C ₂₊ hydrocarbon fraction separation unit, which includes a compressor section of the first expander-compressor unit located on the line of purified and dried gas, the main multi-flow heat exchanger, a separator equipped with separation and residue gas outlet lines separation, wherein the separation gas outlet line is divided into the first and second separation gas supply lines, the separation residue outlet line is divided into the first and second separation residue supply lines, while the first separation residue supply line is connected to the first separation gas supply line equipped with an upper multi-flow heat exchanger , a reducing valve and connected to the upper part of the distillation column, the supply line of the second separation residue is equipped with a reducing valve and is connected to the middle part of the distillation column, the supply line of the second separation gas is equipped with an expander section of the first th expander-compressor unit and is connected to the middle part of the distillation column above the supply line of the second separation residue, in addition, the top of the distillation column is equipped with a residual gas outlet line, on which the upper heat exchanger, main heat exchanger, connection with a branch of the second circulation gas after the compressor section are located in series of the second expander-compressor unit, a compressor unit, a refrigerator, a branch of the first circulation gas and a branch of the second circulation gas, wherein the branch of the first circulation gas is equipped with a main heat exchanger, an upper heat exchanger and a reducing valve and is connected to the upper part of the distillation column above the supply line of the first separation gas, and branch of the second circulating gas is equipped with an expander section of the second expander-compressor unit, an upper heat exchanger, a main heat exchanger, a compressor section of the second expander-compressor unit the bottom of the distillation column is connected to the main heat exchanger by the input/output lines of the first and second circulating refluxes, and the bottom of the distillation column is connected to the main heat exchanger by the line for the output of the C ₂₊ fraction of hydrocarbons, a feature is that a separator is installed on the supply line of the second separation gas in front of the distillation column, connected to the distillation column by the supply line of the third separation residue, and to the residual gas output line - by the supply line of the third separation gas, in addition, on the supply line of the mixture of the first separation gas with The first separation residue in front of the distillation column is also equipped with a separator connected to the distillation column by the fourth separation residue supply line, and with the residual gas outlet line - by the fourth separation gas supply line.

If necessary, a separator is also installed on the branch of the first circulating gas before the distillation column, connected to the distillation column by the supply line of the fifth separation residue, and to the line of residual gas output - by the supply line of the fifth separation gas.

If necessary, the bottom of the distillation column can be equipped with a heater connected to the line of purified and dried gas before and after the main heat exchanger by the input/output line of its part.

If necessary, the bottom of the distillation column of the C ₂₊ hydrocarbon fraction separation unit is equipped with an additional heater with an external coolant.

If necessary, the gas processing plant additionally includes gas purification and drying units, as well as a unit for separating the C ₂₊ hydrocarbon fraction.

The compressor unit and compressor sections of expander-compressor units can be equipped with compressed gas cooling systems. Separators can be tubular or capacitive. The distillation column is equipped with packed, film or tray internal contact devices. The remaining components of the gas processing plant can be made in any way known from the prior art.

The gas processing plant is shown in the diagram and includes the first expander-compressor unit 1 with compressor section 2 and expander section 3, the second expander-compressor unit 4 with compressor section 5 and expander section 6, compressor unit 7, multiflow heat exchangers 8 (main) and 9 ( upper), air cooler 10, separators 11, 12 and 13, reducing valves 14-16, distillation column 17, pump 18. If necessary, the installation may additionally include a separator 19.

During the operation of the gas processing plant, the purified and dried gas supplied through line 20 is compressed in the compressor section 2 of the expander-compressor unit 1, cooled in the heat exchanger 8 and sent to the separator 11, from the top of which the separation gas is discharged through line 21, which is divided into streams of the first 22 and second 23 gas separation. From the bottom of the separator 11 through line 24 remove the separation residue, which is divided into streams of the first 25 and second 26 separation residue. The second separation residue 26 is reduced in the reducing valve 14 and sent to the middle part of the column 17. The second separation gas 23 is reduced in the expander section 3 of the expander-compressor unit 1 and sent to the separator 12, from the top of which the third separation gas is sent through line 27 to the line of residual gas 29 to the heat exchanger 9. From the bottom of the separator 12 through line 28, the third separation residue is sent to the middle part of the column 17 above the supply line of the second separation residue 26. The first separation residue 25 is mixed with the first separation gas 22, cooled in the heat exchanger 9, reduced in the reducing valve 15 and is sent to the separator 13, from the top of which the fourth separation gas is sent through line 34 to the residual gas line 29 to the heat exchanger 9, and the fourth separation residue is fed into the upper part of the column 17.

From the top of the column 17 through line 29, the residual gas enriched in methane is removed, mixed with the third and fourth separation gases 27 and 34 and heated in heat exchangers 9 and 8, then mixed with the second circulating gas 31, compressed in the compressor unit 7, cooled in the refrigerator 10 , then the first (line 30) and second (line 31) circulating gases are taken, and then sent to consumers. The first circulation gas 30 is cooled in heat exchangers 8 and 9, reduced in the reducing valve 16 and sent as phlegm to the upper part of the column 17 above the supply line for the mixture of the first separation gas 22 with the first separation residue 25. The second circulation gas 31 is sent for expansion to the expander section 6 of the expander-compressor unit 4 and further as a cooling medium is fed into heat exchangers 9 and 8, then it is compressed in the compressor section 5 of the expander-compressor unit 4 and mixed with the residual gas stream 29 before the compressor unit 7. From the bottom of the column 17 through lines 32 and 33 to/from the heat exchanger 8 enter/exit the first and second circulation irrigations, respectively. From the bottom of the column 17 through line 35, the pump 18 removes the hydrocarbon fraction C ₂₊ after preheating in the heat exchanger 8.

If necessary, a separator 19 is installed on the branch of the first circulation gas 30 before the column 17, from which the fifth separation residue is supplied to the column 17, and the fifth separation gas is sent to line 29 via line 36.

If necessary, the bottom of the column 17 can be equipped with a heater, into which a part of it is introduced/removed from the line of purified and dried gas 20 before and after the main heat exchanger 8. If necessary, the bottom of the column 17 is heated using an additional heater with an external coolant (not conventionally shown in the diagram).

If necessary, at the gas processing plant, purified and dried gas is obtained at an additional unit for cleaning and drying the feed gas, and the C ₂₊ hydrocarbon fraction is sent for fractionation to an additional separation/gas fractionation unit (not shown in the diagram).

The operability of the installation is confirmed by an example.

100,000 nm ³ /hour of purified and dried hydrocarbon gas containing, % vol.: methane 70.62; ethane 13.63; nitrogen 2.39; carbon dioxide 0.73; hydrocarbons C ₃₊ the rest, at plus 20 ºС and 5.2 MPa, are compressed in the compressor section 2 of the expander-compressor unit 1 to 7.1 MPa, cooled in the heat exchanger 8 to a temperature of minus 7 ºС and sent to the separator 11, from the top of which lines 21 output 79120 nm ³ /hour of separation gas, which is divided into equal flows of the first separation gas 22 and the second separation gas 23. From the bottom of the separator 11 through line 24 output 30.5 t/h of the separation residue, which is divided into 0.5 t /hour of the first separation residue 25 and the second 26 separation residue. The second separation residue 26 is reduced in the reducing valve 14 to 1.71 MPa and at a temperature of minus 34 ºС is sent to the middle part of the distillation column 17. The second separation gas 23 with a flow rate of 39560 nm ³ /hour is reduced in the expander section 3 of the first expander-compressor unit 1 up to 1.71 MPa and at a temperature of minus 59 ºС is sent to the separator 12, from the top of which the third separation gas with a flow rate of 34910 nm ³ / hour is sent for mixing into the residual gas line to the upper heat exchanger 9. From the bottom of the separator 12 7.27 t / an hour of the third separation residue is sent to the middle part of the distillation column 17 above the supply line of the second separation residue 26. The first separation residue 25 is mixed with the first separation gas 22, cooled in the heat exchanger 9 to minus 50 ºС, reduced in the reducing valve 15 to 1.71 MPa and at a temperature of minus 91 ºС, they are divided in separator 13 into 26420 nm ³ / hour of the fourth separation gas, which is sent to the residual gas line, and 15.7 t / hour of the fourth stop Separation oil, which is fed into the upper part of the distillation column 17.

From the top of the distillation column 17 with a temperature of minus 101 ºС, the residual gas 29, enriched in methane, is removed at a flow rate of 47710 nm ³ / hour, mixed with the third 27 and fourth 34 separation gases, the mixture is heated in heat exchangers 9 and 8 to plus 35 ºС, mixed with flow 31, compressed in compressor 7 to 7.93 MPa, cooled in a refrigerator 10 to 20 ºС and then sent to consumers in the amount of 77510 nm ³ /hour.

Part of the residual gas flow after the cooler 10 along the branch of the first circulation gas 30 in the amount of 32300 nm ³ /hour is cooled in the main heat exchanger 8 and the upper heat exchanger 9 to a temperature of minus 60 ºС, reduced in the reducing valve 16 to 1.71 MPa and sent to the upper part distillation column above the feed line of the mixture of the first separation gas 22 with the first separation residue 25 as reflux. Part of the residual gas flow after the cooler 10 along the branch of the second circulating gas 31 in the amount of 51670 nm ³ /hour is reduced in the expander section 6 of the second expander-compressor unit 4 to 1.71 MPa and then fed into heat exchangers 9 and 8 as a cooling medium, then compressed in the compressor section 5 of the second expander-compressor unit 4 to 2.2 MPa and mixed with the flow 29 of the residual gas before the compressor 7.

From the lower part of the distillation column 17 (4th plate, hereinafter - below) along the branch of the first circulating irrigation through line 32 with a temperature of minus 28 ºС, liquid is taken in the amount of 3 t/h and sent for heating to the main heat exchanger 8, then returned back to distillation column 17 as reflux with a temperature of minus 5 ºС (on the 3rd plate). From the lower part of the distillation column 17 (2nd plate) along the branch of the second circulating irrigation line 33 with a temperature of minus 2 ºС, liquid is taken in the amount of 3 t/h and sent for heating to the main heat exchanger 8, then returned back to the distillation column 17 in as a phlegm with a temperature of plus 10 ºС (on the 1st plate). From the bottom of the distillation column 17 through line 35, pump 18 removes the hydrocarbon fraction C ₂₊ in the amount of 43.1 t/h, containing, % vol.: methane 0.66; ethane 45.34; carbon dioxide 1.47, the rest - hydrocarbons С ₃₊ , after preheating in a heat exchanger 8 to 16 ºС.

At the same time, under the conditions of the example, the ethane recovery depth was 77.1%, the maximum actual gas flow in the upper part of the distillation column was 1267 m ³ /h, and the calculated diameter of the upper part of the column was 1.189 m.

At the facility under prototype conditions, the ethane recovery depth was 73.9%, the maximum actual gas flow in the upper part of the distillation column was 3305 m ³ /h, and the estimated diameter of the upper part of the column was 1.837 m.

Thus, the proposed gas processing plant makes it possible to increase the degree of extraction of the C ₂₊ hydrocarbon fraction, to reduce the diameter of the upper part of the distillation column, and can be used in industry.

Claims (5)

1. A gas processing plant, including a C ₂₊ hydrocarbon fraction separation unit, which includes a compressor section of the first expander-compressor unit located on the line of purified and dried gas, a main multi-flow heat exchanger, a separator equipped with separation gas and separation residue outlet lines, and the gas outlet line separation line is divided into supply lines of the first and second separation gases, the separation residue output line is divided into supply lines of the first and second separation residues, while the supply line of the first separation residue is connected to the supply line of the first separation gas, equipped with an upper multi-flow heat exchanger, a reducing valve and connected to the upper part of the distillation column, the supply line of the second separation residue is equipped with a reducing valve and is connected to the middle part of the distillation column, the supply line of the second separation gas is the middle part of the distillation column above the supply line of the second separation residue, in addition, the top of the distillation column is equipped with a residual gas outlet line, on which the upper heat exchanger, the main heat exchanger, the connection with the branch of the second circulation gas after the compressor section of the second expander-compressor unit, the compressor unit , a refrigerator, a branch of the first circulating gas and a branch of the second circulating gas, wherein the branch of the first circulating gas is equipped with a main heat exchanger, an upper heat exchanger and a reducing valve and is connected to the upper part of the distillation column above the supply line of the first separation gas, and the branch of the second circulating gas is equipped with an expander section of the second expander-compressor unit, the upper heat exchanger, the main heat exchanger, the compressor section of the second expander-compressor unit and is connected to the residual gas outlet line unit of the compressor unit, in addition, the lower part of the distillation column is connected to the main heat exchanger by input/output lines of the first and second circulating irrigation, and the bottom of the distillation column is connected to the main heat exchanger by the line for outputting the C ₂₊ fraction of hydrocarbons, characterized in that on the second gas supply line separation, a separator is installed before the distillation column, connected to the distillation column by the supply line of the third separation residue, and with the residual gas outlet line - by the supply line of the third separation gas, in addition, a separator is also installed on the supply line of the mixture of the first separation gas with the first separation residue before the distillation column , connected to the distillation column by the fourth separation residue supply line, and to the residual gas outlet line - by the fourth separation gas supply line. 2. The gas processing plant according to claim 1, characterized in that a separator is installed on the branch of the first circulating gas in front of the distillation column, connected to the distillation column by the supply line of the fifth separation residue, and with the residual gas output line - by the supply line of the fifth separation gas. 3. Gas processing plant according to claim 1, characterized in that the bottom of the distillation column is equipped with a heater connected to the line of purified and dried gas before and after the main heat exchanger by the input / output line of its part. 4. The gas processing plant according to claim 1, characterized in that the bottom of the distillation column of the C ₂₊ hydrocarbon fraction separation unit is equipped with an additional heater with an external coolant. 5. Gas processing plant according to claim 1, characterized in that it additionally includes gas purification and drying plants, as well as a C ₂₊ hydrocarbon fraction separation unit.

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