RU20785U1 - INSTALLATION OF FRACTIONATION OF GAS AND LIQUID FLOWS OF HYDROCARBONS - Google Patents

Abstract

An apparatus for fractionating gaseous and liquid hydrocarbon streams, comprising a condensate stabilization unit by heating, connected to an unstable gas condensate supply line and stable condensate and stabilization gas exhaust lines, first, second and third amine units for cleaning acidic components and drying with crude feed lines natural gas, while the outputs of the first and second blocks of amine purification from acidic components and drying are connected respectively through the first and second blocks of adsorption sewage from mercaptans by the purified gas supply lines with the first and second units for the separation of the ethane fraction and the wide fraction of light hydrocarbons by low-temperature condensation and rectification, the outputs of which are connected to the rectification separation unit of the wide fraction of light hydrocarbons, the purified gas supply line to the second block of the separation of the ethane fraction and a wide fraction of light hydrocarbons by means of low-temperature condensation and rectification is equipped with a line for the removal of commercial gas, the output of the third block of amine removal of acidic components and drying unit is connected to the discharge of propane-butane fraction by low-temperature oil absorption, characterized in that the line retraction stabilization gas supply line is connected to the crude gas in the first block of the amino acid components of cleaning and drying.

Description

INSTALLATION OF FRACTIONATION OF GAS-SHAPED AND LIQUID NOTES OF HYDROCARBONS

The utility model relates to the non-processing of gaseous and liquid hydrocarbons, namely, oil and natural gases and gas condensates in order to produce marketable gas, ethane, nronane-butane, pentanehexane fractions and stable gas condensate, and can be used in enterprises of the gas and oil industry.

A known installation for fractionation of gas and liquid hydrocarbon streams Ci-Sb, containing lines for supplying a gas and liquid hydrocarbon stream to a fractionating absorber-stabilizer system, where light hydrocarbons (Ci-Ci) are separated, and distillation columns for separate fractionation of a stable deethanized residue (heavy hydrocarbons) ) and the selected stream of light hydrocarbons - ethane-containing gas into individual hydrocarbons 1.

A disadvantage of the known installation is the high operating costs associated with the separate processing of the selected ethane-containing gas.

The closest to the claimed purpose, the set of essential features and the achieved result is currently used at the Orenburg gas processing complex, including the Orenburg gas processing plant (OGNZ) and the Orenburg helium (OGZ) plants, installation of fractionation of gaseous and liquid hydrocarbon streams, providing for the separation of three separate hydrocarbon streams, natural gas and unstable gas condensate stream 2.

The currently used installation (see the attached drawing) provides for parallel amine purification of acidic components (hydrogen sulfide and carbon dioxide) and glycol drying of three streams of raw natural gas in the first, second and third stages of the gas treatment plant (blocks 1, 2 and 3, respectively by lines 4, 5 and 6 of supplying raw natural gas to them), followed by purification from mercaptans on blocks 7, 8, 9. Then, purified from acidic components and mercaptans and dried natural gas, it is subjected to the following processing:

the first natural gas stream at block 10 of low-temperature condensation and distillation (at the second and third stages of the OGZ) is cooled in the system of expanders and refrigerators to the condensation temperature, then it is sent to a demethanizer to separate the methane fraction, to a deethanizer, the top product of which is the ethane fraction, and the bottom - a wide fraction of light hydrocarbons (BFLH);

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fractionation and rectification to obtain methane, ethane fractions and NGL;

BFLH, which is used for processing the first and second gas streams, is subjected to fractionation on a rectification separation unit 11 to obtain propane-butane (PBP) and pentane-hexane (PHF) fractions.

PBF is extracted from the third stream at block 9 of low-temperature oil absorption (at stage III of the OGPZ).

The stream of heated unstable gas condensate is divided into heavy hydrocarbons (stable condensate) and lighter ones - ethane-containing gas (stabilization gases) on block 15 (OGPZ line), the outlets of which are connected to the stable condensate tap line 16 and stabilization gas tap line 17a (shown with a dashed line ) The stabilization gases through line 17a are fed into the feed gas lines 5 and 6 at the P and III stages of the gas treatment plant, where they are mixed with the second and third streams of crude gas before they are amine-purified from acid components and dried for joint subsequent processing to separate the ethane fraction and BFLH at block 13 (with the subsequent separation of BFLH into PBF and PGF at block 11) and PBF at block 9.

The supply of separated light hydrocarbons (stabilization gases) to the second and third stages of OGPZ allows them to be cleaned of acidic components and processed using existing equipment.

However, in general, the known installation has insufficient ethane productivity due to the fact that the product used in the processing of stabilization gas mixed with a third gas stream is PBP, and the second gas stream, the products of which are the ethane fraction and NGL (a then BFLH is fractionated with the release of PBP and PHF), it is processed in a volume of only 20%. At the same time, stabilization gases are a valuable ethane-containing sulfate (14-17% vol. € 2).

In addition, the known installation does not allow sufficiently fully to isolate from stabilization gases contained in them in an amount of 24-27% vol. Сз-С4 hydrocarbons (PBP) due to the insufficiently high recovery coefficients of the target products by the method of low-temperature oil absorption used for processing the third gas stream. Processing this gas stream also does not provide for the evolution of Cs-Ce hydrocarbons (PHF).

This does not allow to highlight the target products in full.

The inventive utility model solves the problem of increasing the productivity of the installation to increase the production of target products (ethane fraction, PBF, PHF) due to more complete utilization of gas condensate stabilization gases.

This problem is solved in the inventive installation of fractionation of gaseous and liquid hydrocarbon streams, providing for the separate processing of three streams of raw natural gas and a stream of unstable gas condensate, containing a condensate stabilization unit by heating, connected to the supply line of unstable gas condensate and the lines of the discharge of stable condensate and stabilization gases, the first, second and third blocks of amine purification from acidic components and drying with feed lines in them raw natural ha for, while the outputs of the first and second blocks of amine purification from acidic components and drying are connected respectively through the first and second blocks of adsorption purification of mercaptans by supply lines of pure gas with the first and second blocks of the separation of the ethane fraction and the wide fraction of light hydrocarbons by means of low-temperature condensation and rectification the outputs of which are connected to a rectification separation unit for a wide fraction of light hydrocarbons, wherein the purified gas supply line to the second ethane fraction separation unit and a wide fraction of light hydrocarbons by means of low-temperature condensation and rectification is equipped with a commercial gas exhaust line, the output of the third block of amine purification from acidic components and drying is connected to a propane-butane fraction separation unit by low-temperature oil absorption, the stabilization gas exhaust line is connected to the raw natural gas supply line in the first block of amine purification from acidic components and drying.

A distinctive feature of the proposed technical solution is the connection of the stabilization gas exhaust line to the supply line of sfth gas to the first block of amine purification from acidic components and drying.

The technical result obtained in this case consists in providing the possibility of a more complete utilization of valuable raw materials — stabilization gases by mixing them with the first stream of natural gas, which after amine purification from acidic components and waste) Sch1ki is completely fractionated by low-temperature condensation and rectification with the separation of the ethane fraction and BFLH, followed by the separation of PBF and PHF from BFLH, which allows to increase the performance of the plant for ethane, PBF and PFF without additional; s costs. At the same time, a slight decrease in the volume of PBP obtained at the low-temperature oil absorption unit is compensated by a significantly larger increase in the volume of PBP in the low-temperature condensation and rectification unit due to the higher recovery coefficient of the target product.

PA drawing shows a block diagram of the proposed installation fractionation of gaseous and liquid hydrocarbon streams.

The proposed installation for fractionation of gaseous and liquid hydrocarbon streams includes units 1, 2 and 3 of amine purification from acidic components and drying with supply lines 4, 5 and 6, respectively, of the first, second and third streams of raw natural gas. Blocks 1 and 2 of amine purification from acidic components and drying of the first and second streams of natural gas are connected to blocks 7 and 8 of adsorption purification from mercaptans, block 3 of amine purification from acidic components and drying of raw gas of the third stream is connected to block 9 of low-temperature

oil absorption. The adsorption purification unit 7 of mercaptans is connected to the ethane fraction separation unit and BFLH 10 by low-temperature condensation and distillation, the output of which is connected to the BFLU distillation separation unit 11. The adsorption purification unit 8 from mercaptans by the purified gas supply line 12 is connected to the ethane fraction separation unit 13 and NGL by low-temperature condensation and rectification, the output of which is connected to the NGL rectification separation unit 11. LEMIA 12 supply of purified gas is connected to the line 14 of the removal of commercial gas into the main gas pipeline. The outputs of the gas condensate stabilization unit 15 are connected to the stable gas condensate drain line 16 and the stabilization gas exhaust line 17 provided with a compressor. The stabilization gas exhaust line 17 is connected to the raw natural gas supply line 4 of the first stream to the amine cleaning unit 1 of acidic components and drying.

The proposed installation works as follows.

Crude gas in three streams along lines 4, 5 and 6 is directed to blocks 1, 2 and 3 of amine purification from acidic components and. Next, the first and second streams of purified from acidic components and drained gas are fed to blocks 7 and 8 of adsorption purification from mercaptans. The third stream is fed to the low-temperature oil absorption unit 9, where it is subjected to the following processing: it is cooled to -30 ° C in a propane evaporator and purified from mercaptans in an oil absorber, where the kerosene fraction (Cd-Cn) is used as the absorption oil, at the same time with mercaptans, absorption oil absorbs hydrocarbons. The gas purified from mercaptans through recuperative heat exchangers enters the commercial gas pipeline (not shown in the drawing). The propanbutane fraction is isolated from the saturated absorption oil in the debutanization column.

The second natural gas stream after adsorption purification from mercaptans at block 8 is routed along line 12, where it is divided into two streams: most of the gas (up to 80%) is routed along line 14 of the commercial gas outlet to the main gas pipeline, and a smaller (20%) is fed to block 13 of low-temperature condensation and rectification, where it is cooled in the system of expanders and refrigerators to a condensation temperature, then sent to a demethanizer to isolate the methane fraction (commercial gas), to a deethanizer, the top product of which is ethano the first fraction, and the lower - the wide fraction of light hydrocarbons (NGL).

The first natural gas stream after purification from mercaptans at block 7 is directed to block 10 for separating the ethane fraction and the first fraction of light hydrocarbons by low-temperature condensation and rectification, where it is cooled in the system of expanders and refrigerators to the condensation temperature, then it is sent to the demethanizer to recover the methane fraction (commercial gas) into a deethanizer, the top product of which is the ethane fraction, and the bottom is the wide fraction of light hydrocarbons (BFLH).

Commodity gas obtained from the top of the demethanizers of blocks 10 and 13 for separating the ethane fraction and BFLH by low-temperature condensation and distillation is sent to the main gas pipeline; the ethane fraction is sent to the ethanowire; NGL is fed to block 11 for separation into PBF and PHF.

The stream of unstable gas condensate after heating enters the gas condensate stabilization unit 15, where the first and second degassing stages are successively carried out. The light hydrocarbon fractions separated out from it - stabilization gases are sent via line 17 through the compressor to mix with the first raw natural gas stream to line 4. In the mixture with the first natural gas stream, the gas condensate stabilization gases go through the entire cycle of cleaning acid components and drying on block 1, purification from mercaptans on block 7, fractionation by low-temperature condensation and rectification on block 10 with separation of ethane fraction and BFLH and further production of PBP and PHF on block 11 of rectification Discount separation of NGL.

Thus, the proposed installation provides for the processing of gas condensate stabilization gases on existing equipment in conjunction with the raw natural gas of the first stream: purification from sulfur compounds and carbon dioxide and refueling, purification from mercaptans, fractionation. In this case, in contrast to the prototype, a more complete utilization of stabilization gases is achieved, not only due to the extraction of ethane, but also due to a more complete extraction of PBP, as well as the production of PHF.

A certain decrease in the volume of obtained PBP at the low-temperature oil absorption unit at the OGPZ stage III due to the supply of stabilization gases is primarily compensated by its significantly larger increase at the low-temperature condensation and rectification unit.

As a result of the connection according to the proposed utility model of the stabilization gas exhaust line (composition is given in the table) of gas condensate with a feed line of raw natural gas of the first stream, the content of ethane in the latter will increase from 4.0 to 4.35% vol., Propane from 1, 68 to 2.3% vol. and butane - from 0.79 to 1.1% vol.

Table

The additional volumes of ethane and PBF used due to the enrichment of the processed raw materials with ethane, propane and butane stabilization gases will amount to 34 and 211 thousand tons per year, respectively.

Thus, the use of the proposed utility model will allow for more complete utilization of gas condensate stabilization gases without additional equipment and capital investments, while improving the plant's ethane and PBF performance.

Claims (1)

Installation for fractionation of gaseous and liquid hydrocarbon streams, comprising a condensate stabilization unit by heating, connected to an unstable gas condensate supply line and stable condensate and stabilization gas removal lines, first, second and third amine units for cleaning acidic components and drying with crude feed lines natural gas, while the outputs of the first and second blocks of amine purification from acidic components and drying are connected respectively through the first and second blocks of adsorption sewage from mercaptans by the purified gas supply lines with the first and second units for the separation of the ethane fraction and the wide fraction of light hydrocarbons by low-temperature condensation and rectification, the outputs of which are connected to the rectification separation unit of the wide fraction of light hydrocarbons, the purified gas supply line to the second block of the separation of the ethane fraction and a wide fraction of light hydrocarbons by low-temperature condensation and rectification is equipped with a line for the removal of commercial gas, the output of the third block of amine removal of acidic components and drying unit is connected to the discharge of propane-butane fraction by low-temperature oil absorption, characterized in that the line retraction stabilization gas supply line is connected to the crude gas in the first block of the amino acid components of cleaning and drying.