RU2722255C1 - Gas processing complex layout - Google Patents

Abstract

FIELD: oil, gas and coke-chemical industries.

SUBSTANCE: invention relates to development and design of gas processing complex and can be used for gas processing industry. Assembly of gas processing complex consisting of one or several lines, each of which includes process links and objects of general-purpose purpose, it is supplemented with a link of the central process trestle, which is uniform for each queue, which connects link and inter-chain pipelines, and link of inter-shop trestles connecting queues and objects of general-industrial facilities. In each queue, process links are connected in series to both sides of link of central process trestle, divided into four sections, forming together with corresponding process links production zones. Process links are supplied with resources from general-purpose plant objects by means of a link of inter-shop bridges through a link of a central technological ramp.

EFFECT: invention makes it possible to reduce auxiliary transport communications, simplify arrangement of additional lines of gas processing complex, to provide variability of layout for optimum functioning of complex.

13 cl, 3 dwg

Description

The invention relates to the development and design of a gas processing complex and can be used for gas processing facilities in the conditions of its intensive development.

Modern gas processing plants usually have several phases, which are built and put into operation as the natural gas production zone expands or the field productivity increases, and are large-scale production complexes that provide high-quality commercial natural gas, liquefied natural gas and additional hydrocarbon products with large general purpose systems. Therefore, its layout, which will allow to gradually put into operation each new line, is essential for the economical functioning of the future enterprise.

The known layout of the enterprise, which includes many triangular blocks combined to form a polygonal shape, in particular hexagons, interconnected along one of the ribs (patent US 6748704, IPC E04H 1/00, E04H 9/00, E04H 5/00, E04H 5/02, announced 02.16.2001, published 06.15.2004). The disadvantages of the invention are:

- the possibility of placing bulky equipment only in the central part of the triangular blocks;

- the difficulty of implementing the combination of triangular blocks in a compact hexagonal shape due to the need to form gaps between the blocks of the gas processing enterprise from the standpoint of fire safety;

- restriction of the conveyor scheme of the organization of production for a gas processing enterprise with a branching technological scheme.

Known gas processing and gas-chemical complex, including gas processing sector, consisting of a unit for the preparation of raw materials, a link for low-temperature fractionation of raw materials, a unit for producing elemental sulfur, a unit for producing a commodity methane fraction (commercial gas), a unit for producing commodity helium, a unit

receiving the amount of liquefied petroleum gases (LPG) and pentane-

hexane fraction, natural gas liquefaction sector, consisting of a liquefied methane fraction (marketed gas) liquefaction and ethane fraction liquefied section, a gas-chemical sector, consisting of ethylene production unit, propylene production unit, synthesis gas, methanol and higher alcohols production unit, ammonia, the unit for producing polymers, copolymers and the unit for producing ethylene glycols, the condensate preparation sector, consisting of the condensate stabilization unit and the motor fuel receiving unit, while the movement of process flows between adjacent sectors is provided by additional pumping stations (patent RU 2570795 C1, IPC C10G 5/00 , B01D 53/00, B01D 61/00, C07C 7/00, F25J 3/00, announced July 15, 2014, published December 10, 2015). The disadvantages of the invention are:

- compactness of the complex layout, realized only within the design capacities of the gas processing and gas chemical sectors;

- a complex technological scheme of the interconnections between the individual links, which does not allow increasing the power of the individual links due to the installation of additional devices or installations when the conditions of the complex are changing, for example, when changing the composition of the source natural gas;

- inaccessibility of communication for multi-stage production;

- the compelled creation of extended piping systems, energy supply and transport communications.

When creating the invention, the task was to develop the layout of the gas processing complex, which will form the main production line with the structure of the links of technological links and plant-wide objects, minimizing the length of pipeline systems to provide individual links with energy, reagents and water, reduce auxiliary transport communications, simplify the layout of additional queues gas processing complex, to provide layout variations for the optimal functioning of the complex.

The problem is solved by arranging a gas processing complex consisting of one or more identical or different power bursts, each of which includes the following technological units:

a) a natural gas supply line through a gas pipeline from a production manifold or from a gas main;

b) the separation of raw natural gas from liquid products, glycol, methanol;

c) a link for the absorption treatment of natural gas from hydrogen sulfide, carbon sulfide, mercaptans, carbon dioxide, methanol, glycol;

d) a link for adsorption drying of natural gas and purification by molecular sieves of sulfur compounds, mercury, followed by regeneration of the adsorbent by heated gas;

d) a cryogenic separation unit for purified and dried natural gas to produce dry stripped gas (SOG) and a fraction of hydrocarbons C ₂ and higher;

f) a separation unit for a hydrocarbon fraction of C ₂ and higher to obtain an ethane fraction and a fraction of C ₃ and higher;

g) the link of the booster compressor station (DKS) for compressing the LOG to produce marketable natural gas, part of which is liquefied;

h) the separation unit of the fraction With ₃ and higher to obtain propane-butane and pentane-hexane fractions;

i) a unit for purifying the propane-butane fraction from methanol, sulfur compounds;

j) the fractionation unit of the mixed propane-butane fraction with the production of propane and butane fractions;

k) a link for the post-treatment of the ethane fraction to obtain a purified ethane fraction used as a component of the refrigerant for liquefying natural gas;

m) a link for the purification of the propane fraction to obtain a purified propane fraction used as a component of the refrigerant for liquefying natural gas;

m) a unit for the purification of the butane fraction to obtain a purified butane fraction used as a component of the refrigerant for liquefying natural gas;

n) liquefied natural gas unit with the production of liquefied natural gas (LNG);

o) LNG storage unit and stripping gas compression;

as well as the following plant-wide facilities:

p) storage parks of marketable products, in particular ethane and / or propane and / or butane and / or pentane-hexane fractions;

c) nitrogen-air station;

r) flare;

s) fuel system;

f) chemical parks;

x) hot water and / or steam boiler room;

c) energy facilities;

h) water supply, sanitation, heat and gas supply facilities;

sh) a system for the shipment of marketable products to motor vehicles and / or railway tanks and / or vessels;

y) facilities for auxiliary and service purposes plant management, laboratories, warehouses, canteen, health center;

at the same time, the gas-pumping complex is supplemented by a link of the central technological flyover (s), which is uniform for each line, connecting link and inter-link pipelines, and a link of inter-shop flyovers (e), connecting the lines and plant facilities, in each turn technological links (a) - (p ) are sequentially connected to both sides of the link (s), divided into four sections, which, together with the corresponding technological links (a) - (p), form production zones, the technological links (a) - (g) are connected to the first section of the link (s) ) with the formation of a production zone for purification of natural gas from impurities, technological units (e) - (g) are connected to the second section of the link (s) with the formation of a production zone for extracting C ₂ and higher hydrocarbons from natural gas, and the third section of the link (s) is connected technological units (h) - (k) with the formation of a production zone for the processing of hydrocarbons C3 and above, to the fourth section of the unit ( s) connect the technological links (l) - (p) with the formation of the production zone for the preparation of refrigerants and liquefaction of natural gas, and the technological links (a) - (p) supply resources from plant-wide objects (p) - (u) using the link ( e) through the link (s).

The considered layout of the gas processing complex allows, by introducing the links (s) and (e), to combine all piping systems in the link (s) that provide individual links with energy, reagents, water, electric power supply cables, and an information automated process control system

processes (process control system). The technological units (a) - (p) may, depending on their direct connection with the incoming raw and output product streams, be located on one or both sides of the corresponding section of the link (s), forming compact production zones. The advantages of the link (e) connecting the objects of the plant economy (p) - (u) are similar. In general, the linear layout of the gas processing complex, technological units (a) - (p) and unit (s), plant facilities (r) - (u) and unit (e), allows you to place the main on-farm roads along units (s) and ( e), reducing the length of auxiliary transport communications.

It is advisable to use oil-coolant or water vapor coming from the link (s) through the side branch of the flyover in the technological unit (g) to obtain heated regeneration gas, which ensures the variability of the layout of the gas processing complex when using various energy carriers.

It is also advisable to use a gas turbine drive connected to link (s) through the side branch of the flyover or use an electric drive in the technological unit (g) as the drive for the compressor station compressor stations, which ensures the variability of the layout of the gas processing complex.

The production zone for the extraction of C ₂ and higher hydrocarbons from natural gas can be supplemented with a gas cooling unit (s) for cooling commodity natural gas before being sent to consumers.

It is useful to use a cascade of pure refrigerants in the technological unit (o) as a refrigerant for the liquefaction of marketable natural gas.

It is advisable to use a gas turbine drive connected to link (s) through the side branch of the flyover as a compressor drive in the technological link (o).

It is useful to divide the technological unit (p) into two sub-units that are geographically distant from each other, while each unit includes an LNG storage tank, LNG transfer pumps and a stripping gas compressor, the links are connected by a LNG cryogen pipeline and a stripping gas pipeline. This separation of the technological unit (p) into two sub-units is especially advisable when the gas processing complex is located at a large distance from the coast, where the terminals for loading LNG onto tankers are located. This allows:

- to accumulate a shipload of LNG in the product shipping area and reduce the length of the large-capacity cryogen pipeline (tank-tanker), because, as a rule, the peak costs when loading a gas tanker significantly exceed the peak LNG production at the complex;

- to ensure the stable operation of a long cryogenic pipeline between sub-links.

The stripping gas pipelines can connect the technological unit (p) to the factory-wide unit (y) - for compressing and using the stripping gas as a source of fuel gas, and / or the technological unit (g) - for mixing the stripping gas with marketable natural gas, and / or technological unit (o) - for re-liquefaction.

It is advisable to place all air cooling devices used in technological units (a) - (p) on the upper tier of the unit (s), which allows to reduce the territory of the production site of the gas processing complex.

It is also advisable to place communications on the upper tier of the link (s) for connecting the technological links (a) - (p) to the power supply system and the process control system, which will significantly reduce the costs of their placement compared to creating a separate installation of these systems on the territory of the production site.

If there are two or more queues, the link (s) of each queue is connected to one common link (e) or the corresponding identical links of each of the queues are connected to one link (s), provided that part of the plant’s facilities can guarantee the operation of two or more queues, which will ensure the variability of the layout of the gas processing complex, depending on the features of the technical specifications for the design of the complex:

- simultaneous or time-delayed construction of different phases of the complex;

- the specifics of the territory allocated for the construction of the complex (terrain, wind rose, external communications, the possibility of cooperation with existing or under construction enterprises for the supply of electricity, heat, steam, water and other features).

The layout of the gas processing complex is schematically illustrated by figures 1-3:

- figure 1 - layout of the first stage of the gas processing complex;

- figure 2 - the layout of the first stage of the gas processing complex, supplemented by the second stage, when the links of the central technological flyovers (s) of each turn are connected to one common link of the inter-shop flyover (e);

- figure 3 - layout of the first stage of the gas processing complex, supplemented by the second stage, when appropriate

the technological links of each of the queues are connected to one common link of the central technological flyover (s); using the following notation for the first (/ 1) and second (/ 2) queues, respectively:

1/1, 1/2 - the supply line of raw natural gas through a gas pipeline from a production manifold or from a gas main (a);

2/1, 2/2 - a link for the separation of raw natural gas from liquid products, glycol, methanol (b);

3/1, 3/2 - the link for the absorption treatment of natural gas from hydrogen sulfide, carbon sulfide, mercaptans, carbon dioxide, methanol, glycol (c);

4/1, 4/2 - a link of adsorption drying of natural gas and additional purification by molecular sieves of sulfur compounds, mercury;

5/1, 5/2 - link of cryogenic separation of purified and dried natural gas to produce SOG and hydrocarbon fractions C ₂ and higher (d);

6/1, 6/2 - link separation of the fraction of hydrocarbons With ₂ and above to obtain an ethane fraction and fractions With ₃ and above (e);

7/1, 7/2 - a BCS unit for compression of SOG to produce marketable natural gas, part of which is subjected to liquefaction (g);

8/1, 8/2 - the separation unit of the fraction C ₃ and above to obtain propane-butane and pentane-hexane fractions (h);

9/1, 9/2 - link purification of the propane-butane fraction from methanol, sulfur compounds;

10/1, 10/2 - the fractionation unit of the mixed propane-butane fraction with the production of propane and butane fractions (k);

11/1, 11/2 - a link for the post-treatment of the ethane fraction to obtain a purified ethane fraction used as a refrigerant component for liquefying commercial natural gas (l);

12/1, 12/2 - a post-treatment unit of the propane fraction to obtain a purified propane fraction used as a refrigerant component for liquefying natural gas (m);

13/1, 13/2 - a unit for the purification of the butane fraction to obtain a purified butane fraction used as a refrigerant component for liquefying commercial natural gas (n);

14/1, 14/2 - liquefied natural gas liquefied unit with the production of LNG (o);

15/1, 15/2 - LNG storage link and stripping gas compression (p);

16/1, 16/2 - the link of the central technological flyover, common for the whole line, connecting the link and interlink pipelines (s);

17/1 - inter-shop flyover link connecting lines and objects

factory economy (e);

18/1 - storage parks of marketable products (ethane and / or propane and / or butane and / or pentane-hexane fraction) (p);

18/2 - additional tanks and pumps in the storage park of commercial products (ethane and / or propane and / or butane and / or pentane-hexane fraction) (p);

19/1 - nitrogen-air station (s);

19/2 - additional block module for the production of nitrogen and air (s);

20/1 - flare (t);

21/1 - fuel system (s);

22/1 - parks of chemical reagents (f);

23/1 - water and / or steam boiler room (x);

23/2 - additional boilers for the production of water vapor and hot water (x);

24/1 - energy facilities (c);

24/2 - additional energy facilities (c);

25/1 - objects of water supply, water disposal, heat and gas supply (h);

26/1 - system for the shipment of marketable products to motor vehicles and / or railway tanks and / or ships (w);

26/2 - additional risers of loading in vehicles (w);

27/1 - facilities for utility and servicing purposes, a plant administration, laboratories, warehouses, a canteen, a health center and other facilities (Щ);

100/1, 100/2 - production zone for the purification of natural gas from impurities;

200/1, 200/2 - production zone for the extraction of hydrocarbons C2 and higher from natural gas;

300/1, 300/2 - production zone for the processing of hydrocarbons C3 and above;

400/1, 400/2 - production area for the preparation of refrigerants and natural gas liquefaction.

The layout of the first stage of the gas processing complex according to Figure 1 is adapted to the construction of the next phases of the complex through the use of a link of the central technological flyover (s) 16/1, connecting link and interlink pipelines, with a full set of communications (pipelines, power electric cables, process control systems) and a link interdepartmental flyover (e) 17/1, connecting the queue and the objects of the plant.

In accordance with the claimed arrangement, the technological links 1 / 1-15 / 1 are placed on one and / or both sides of the 16/1 link, minimizing the length of inter-link pipelines for moving technological products of natural gas processing and auxiliary pipelines for supplying energy, water, reagents, at the same time, the 16/1 link is connected to the 17/1 link connected to the plant facilities 18 / 1–27 / 1.

When arranging the second stage of the gas processing complex, in addition to the already existing first stage, the technological links 1 / 2–15/2 are placed on both sides of the 16/2 link (Figure 2) or the 16/1 link (Figure 3), for which they are already used existing link 17/1. In this case, the capacity of the plant facilities 18 / 1–27 / 1 is insufficient for the operation of the technological facilities of the second stage, therefore, the plant facilities include plant facilities 18/2, 19/2, 23/2, 24/2, 26/2 .

Thus, the claimed invention solves the problem of developing the layout of a gas processing complex, which allows to form the main technological line with the structure of the links of technological links and plant-wide objects, minimizing the length of pipeline systems to provide individual links with energy, reagents and water, reduce auxiliary transport communications, simplify the layout of additional queues gas processing complex, to provide layout variations for the optimal functioning of the complex.

Claims (40)

1. The layout of the gas processing complex, consisting of one or more of the same or different power bursts, each of which includes the following technological units: a) a natural gas supply line through a gas pipeline from a production manifold or from a gas main; b) the separation of raw natural gas from liquid products, glycol and methanol; c) a link for the absorption treatment of natural gas from hydrogen sulfide, carbon sulfide, mercaptans, carbon dioxide, methanol; d) a link for adsorption drying of natural gas and purification by molecular sieves of sulfur compounds, mercury, followed by regeneration of the adsorbent by heated gas; d) a cryogenic separation unit for purified and dried natural gas to produce dry stripped gas (SOG) and a fraction of hydrocarbons C ₂ and higher; f) a separation unit for a hydrocarbon fraction of C ₂ and higher to obtain an ethane fraction and a fraction of C ₃ and higher; g) the link of the booster compressor station (DKS) for compressing the LOG to produce marketable natural gas, part of which is liquefied; h) the separation unit of the fraction With ₃ and higher to obtain propane-butane and pentane-hexane fractions; i) a unit for purifying the propane-butane fraction from methanol, sulfur compounds; j) the fractionation unit of the propane-butane fraction with the production of propane and butane fractions; k) a link for the post-treatment of the ethane fraction to obtain a purified ethane fraction used as a component of the refrigerant for liquefying natural gas; m) a link for the purification of the propane fraction to obtain a purified propane fraction used as a component of the refrigerant for liquefying natural gas; m) a unit for the purification of the butane fraction to obtain a purified butane fraction used as a refrigerant component to liquefy natural gas; n) liquefied natural gas unit with the production of liquefied natural gas (LNG); o) LNG storage unit and stripping gas compression; as well as the following plant-wide facilities: p) storage parks for marketable products, in particular ethane, and / or propane, and / or butane, and / or pentane-hexane fractions; c) nitrogen-air station; r) flare; s) fuel system; f) chemical parks; x) hot water and / or steam boiler room; c) energy facilities; h) water supply, sanitation, heat and gas supply facilities; sh) a system for the shipment of marketable products to motor vehicles and / or railroad tanks and / or ships; y) facilities for utility and maintenance purposes: plant management, laboratories, warehouses, canteen, health center; characterized in that the gas processing complex is complemented by a link of the central technological flyover (s), a single link for each line connecting interconnecting pipelines and inter-link pipelines, and a link of inter-shop flyovers (e) connecting the queues and plant facilities, in each queue technological links (a) - (p) sequentially connect to both sides of the link (s), divided into four sections, forming in combination with the corresponding technological links (a) - (p) production zones, while the technological links (a) are connected to the first section of the link (s) ) - (g) with the formation of a production zone for purification of natural gas from impurities, technological units (e) - (g) are connected to the second section of the link (s) with the formation of a production zone for the extraction of hydrocarbons C ₂ and higher from natural gas, to the third section of the link (s) connect technological units (h) - (k) with the formation of a production zone for the processing of hydrocarbons With ₃ and higher, to h the fourth section of the link (s) connects the technological links (l) - (p) with the formation of a production zone for the preparation of refrigerants and liquefied natural gas, and technological links (a) - (p) supply resources from plant-wide facilities (p) - (u) using link (s) through link (s). 2. The arrangement according to claim 1, characterized in that the process unit (d) uses heat transfer oil or water vapor from the unit (s) through the lateral branch of the flyover to obtain heated regeneration gas. 3. The arrangement according to claim 1, characterized in that in the technological link (g), a gas turbine drive connected to the link (s) through the lateral branch of the flyover is used as the drive of the compressor stations of the BCS. 4. The arrangement according to claim 1, characterized in that in the technological link (g), an electric drive is used as the drive of the compressors. 5. The arrangement according to claim 1, characterized in that the production zone for extracting hydrocarbons C ₂ and higher from natural gas is supplemented with a gas cooling unit (s). 6. The arrangement according to claim 1, characterized in that in the process unit (o), a cascade of pure refrigerants is used as a refrigerant for liquefying commercial natural gas. 7. The arrangement according to claim 1, characterized in that in the process unit (o) a gas turbine drive is used as a compressor drive connected to the link (s) through the side branch of the overpass. 8. The arrangement according to claim 1, characterized in that the technological unit (n) is divided into two sub-units that are geographically distant from each other, while each unit includes an LNG storage tank, LNG transfer pumps and a stripping gas compressor, connect the links LNG cryogen pipeline and stripping gas pipeline. 9. The arrangement according to claim 1, characterized in that the stripping gas pipelines connect the technological unit (p) to the plant-wide unit (y), and / or the technological unit (g), and / or the technological unit (o). 10. The arrangement according to claim 1, characterized in that in the technological links (a) - (p), all used air-cooling devices are placed on the upper tier of the link (s). 11. The arrangement according to p. 10, characterized in that on the upper tier of the link (s), communications are placed to connect the technological links (a) - (p) to the power supply system and the automated process control system. 12. The arrangement according to claim 1, characterized in that in the presence of two or more queues, the link (s) of each queue is connected to one common link (e). 13. The arrangement according to claim 1, characterized in that in the presence of two or more queues, the corresponding technological links (a) - (p) of each of the queues are connected to one link (s).

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