KR101264888B1 - Dimethyl Ether FPSO capable of enhancing oil recovery by using byproducts - Google Patents

Abstract

The present invention relates to a dimethyl ether (DME) floating plant (FPSO, floating production storage and offloading), more specifically, it is possible to generate power while simultaneously producing, storing and unloading DME from natural gas by installing a combustion device, The present invention relates to a DME floating plant capable of improving natural gas production using by-product gas, which uses enhanced gas recovery (EGR) using by-product carbon dioxide and nitrogen.
DME floating plant capable of promoting natural gas production using the by-product gas according to the present invention, in the DME floating plant capable of producing, storing and unloading DME (dimethyl ether), the mixture from the offshore natural gas field (10) Natural gas production unit 200 for producing a natural gas by collecting the; An oxygen generator 400 for separating oxygen and nitrogen from air to produce oxygen and nitrogen; A DME production apparatus 300 receiving some natural gas from the natural gas production unit 200 and receiving oxygen from the oxygen generator 400 to produce a DME; Combustion apparatus 500 for producing the energy used in the DME floating plant by receiving a portion of natural gas from the natural gas production unit 200 to combust; And liquefying the carbon dioxide contained in the exhaust gas discharged from the combustion device 500 by using a portion of nitrogen produced by the oxygen generator 400 as a refrigerant, and supplying the liquefied carbon dioxide to the marine natural gas field 10. It characterized in that it comprises a; carbon dioxide processing unit 600 to promote the production of natural gas.

Description

Dimethyl Ether FPSO capable of enhancing oil recovery by using byproducts}

The present invention relates to a dimethyl ether (DME) floating plant (FPSO, floating production storage and offloading), more specifically, it is possible to generate power while simultaneously producing, storing and unloading DME from natural gas by installing a combustion device, The present invention relates to a DME floating plant capable of improving natural gas production using by-product gas, which uses enhanced gas recovery (EGR) using by-product carbon dioxide and nitrogen.

Floating production storage and offloading (FPSO) are floating on water in deep oil fields, extracting and producing crude oil, storing it in huge tanks under the ship, A ship-type facility that acts as an offloading cargo.

The conventional gas field was a system in which a fixed plant was installed near the coast to transport the mined gas to a pipeline and stored in a storage tank, but as the gas reserves gradually depleted, it is necessary to mine the gas field existing in the sea. With this rise, floating plants can be used to produce natural gas even in the offshore.

In natural gas fields, natural gas is spewed upward by the pressure of water under the gas at the beginning of production.

Generally, natural gas is well mined by underground pressure in the early stage of production, but if the pressure of natural gas field decreases over time, the production of natural natural gas is stopped and a large part of natural gas is produced in natural gas field. Left unproduced.

As such, the production of natural gas by natural ejection by pressure in the natural gas field is called primary recovery.

The natural gas remaining after the first recovery is forcibly recovered by injecting gas into the natural gas or injecting water. This is called secondary recovery.

If it is necessary after the second recovery, a separate substance is injected into the natural gas field and some of the natural gas remaining in the natural gas field is somehow recovered. This is called a third recovery.

Natural gas mined from the seabed is in the form of a mixture of gas, water, oil, etc., so that natural gas is separated from the mixture by separating natural gas, water, and oil.

The method of recovering natural gas that is stored without being produced, such as secondary and tertiary recovery, is called gas enhanced recovery (EGR). More research is needed to lower the production cost of crude oil (oil), resulting in higher production costs.

The present invention has been invented in view of the above circumstances, and has an object to provide a DME floating plant for improving energy efficiency and preventing environmental pollution by taking measures to utilize the by-products of the DME floating plant.

According to an aspect of the present invention for achieving the above object, in the DME floating plant capable of producing, storing and unloading DME (dimethyl ether), by taking a mixture from the offshore natural gas field 10 to produce natural gas Natural gas production unit 200; An oxygen generator 400 for separating oxygen and nitrogen from air to produce oxygen and nitrogen; A DME production apparatus 300 receiving some natural gas from the natural gas production unit 200 and receiving oxygen from the oxygen generator 400 to produce a DME; Combustion apparatus 500 for producing the energy used in the DME floating plant by receiving a portion of natural gas from the natural gas production unit 200 to combust; And liquefying the carbon dioxide contained in the exhaust gas discharged from the combustion device 500 by using a portion of nitrogen produced by the oxygen generator 400 as a refrigerant, and supplying the liquefied carbon dioxide to the marine natural gas field 10. It provides a DME floating plant capable of promoting natural gas production using the by-product gas comprising a; carbon dioxide treatment unit 600 to promote the production of natural gas.

By supplying a portion of the nitrogen produced in the oxygen generator 400 to the offshore natural gas field 10 to promote the production of natural gas.

The DME liquefaction apparatus 310 is installed at the rear end of the DME production apparatus 300 to liquefy the DME produced by the DME production apparatus 300 using a portion of nitrogen produced by the oxygen generator 400 as a refrigerant. ; And a DME storage tank 320 for storing the liquefied DME.

Nitrogen storage tank 450 for storing the nitrogen produced by the oxygen generator 400; further comprising, the nitrogen stored in the nitrogen storage tank 450 to liquefy carbon dioxide in the exhaust gas, in the DME production apparatus It is characterized in that the liquefied DME produced, and is supplied to the marine natural gas field 10 to promote the production of the natural gas.

The natural gas production unit 200, the three-phase separator 210 for producing natural gas by separating the natural gas, oil and water from the mixture; characterized in that it comprises a.

The natural gas production unit 200, receiving the natural gas from the three-phase separator 210 to remove impurities and to supply to the DME production apparatus 300; and further comprises a.

A waste heat recovery device 550 for recovering heat of the high-temperature exhaust gas discharged from the combustion device 500, converting the heat into exhaust gas of normal temperature and atmospheric pressure, and supplying the exhaust gas to the carbon dioxide processing unit 600. It is done.

The carbon dioxide processing unit 600, the pressurizer 620 for pressurizing the pressure above the triple point to liquefy the carbon dioxide contained in the exhaust gas passing through the waste heat recovery device 550; A carbon dioxide liquefaction apparatus (630) installed at a rear end of the pressurizer (620) and using nitrogen produced in the oxygen generator (400) as a refrigerant to liquefy carbon dioxide contained in the exhaust gas passing through the pressurizer (620); A liquefied carbon dioxide separator (640) installed at a rear end of the carbon dioxide liquefier (630) to separate the liquefied carbon dioxide produced by the pressurizer (620) or the carbon dioxide liquefier (630); And a liquefied carbon dioxide injector 660 for injecting the separated liquefied carbon dioxide into the natural gas field 10.

And a liquefied carbon dioxide storage tank 650 for receiving and storing liquefied carbon dioxide separated from the liquefied carbon dioxide separator 660 and supplying liquefied carbon dioxide to the liquefied carbon dioxide injector 660.

The carbon dioxide treatment unit 600 further includes a post-treatment device 610 which removes impurities from the exhaust gas passing through the waste heat recovery device 550 and supplies them to the pressurizer 620.

According to another aspect of the present invention, in the DME floating plant capable of producing, storing and unloading DME (dimethyl ether), the oxygen generator 400 for separating oxygen and nitrogen from the air to produce oxygen and nitrogen; And a DME production apparatus 300 receiving the oxygen produced in the oxygen generator 400 and the natural gas produced in the offshore natural gas field 10 to produce a DME; including, but is generated by burning the natural gas. Promoting the production of natural gas by liquefying carbon dioxide contained in the gas into the nitrogen produced in the oxygen generator 400 to supply to the offshore natural gas field 10; Provide this possible DME floating plant.

Part of the nitrogen produced in the oxygen generator is supplied to the offshore natural gas field 10 to promote the production of the natural gas.

Part of the nitrogen produced in the oxygen generator is to liquefy and store the DME produced by the DME production apparatus 300;

According to the present invention, the DME floating plant is equipped with a combustion device to produce electricity using natural gas and at the same time to produce, store and unload DME from natural gas, and to remove carbon dioxide contained in the exhaust gas of the combustion device. Gas recovery can be enhanced by separating and supplying to the natural gas field.

In addition, after the installation of a separate oxygen generator for the production of DME can be liquefied by cooling the room temperature DME low temperature using nitrogen separated from the air as a refrigerant.

In addition, the carbon dioxide contained in the exhaust gas of the combustion apparatus can be liquefied using nitrogen produced in the oxygen generator as a refrigerant, and the liquefied carbon dioxide can be supplied to the natural gas before gas recovery.

1 schematically shows a DME floating plant according to the invention;
Figure 2 shows in detail the DME floating plant according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the preferred embodiment of the present invention. In the drawings, like reference numerals refer to like elements throughout. The same reference numerals in the drawings denote like elements throughout the drawings.

1 is a view schematically showing a DME floating plant according to the present invention, Figure 2 is a view showing a DME floating plant according to the present invention in detail.

Normal temperature and atmospheric pressure used in the present invention means the temperature and pressure of the general atmosphere, and generally refers to a state of about 15 to 25 ° C. and about 1 atm.

DME is an abbreviation of dimethyl ether and is an ether compound (CH3OCH3) combined with one oxygen molecule and two methane groups.DME is a colorless and odorless fuel, which is a clean fuel with no harmful toxicity to the human body and very little pollutant emissions during combustion. It is classified as new energy and new fuel that will replace fossil fuel in the future as fuel for household, transportation and power generation.

DME can be manufactured not only from coal, but also from biomass, waste plastics, and the like, and its use is widely used for power generation, public welfare, and automobiles, so that demand for DME is expected to increase gradually.

Therefore, the floating plant of the present invention is a DME floating plant capable of producing, storing and unloading DME using natural gas mined from offshore natural gas fields in order to increase the production of DME. It was invented to improve gas recovery using by-products.

As shown in Figure 1, the DME floating plant 100 according to the present invention, natural gas production unit 200, oxygen generator 400, DME production apparatus 300, combustion apparatus 500, carbon dioxide treatment unit 600 It consists of.

The natural gas production unit 200 produces natural gas from the offshore natural gas field 10. The natural gas mined from the offshore natural gas field 10 is in the form of a mixture of gas, water, oil, and the like.

Therefore, the natural gas production unit 200 may be configured as a device capable of separating natural gas from such a mixture, and may preferably include a three-phase separator 210.

The three phase separator 210 separates natural gas, oil and water from the mixture mined from the offshore natural gas field 10.

The natural gas production unit 200 may further include a pretreatment device 220 at the rear end of the three-phase separator 210. The pretreatment device 220 may include impurities contained in the natural gas separated from the three-phase separator 210. For example, mercury or sulfur dioxide) may be removed to prevent damage such as corrosion to the DME production apparatus 300 due to impurities.

The oxygen generator 400 separates oxygen and nitrogen from air to produce oxygen and nitrogen, and compresses, cools, and condenses the air, thereby allowing nitrogen at atmospheric pressure and cryogenic temperature (for example, -188 ° C.). And oxygen (-183 ° C). The cryogenic temperature is an example, and does not necessarily refer to the above temperature, but should be lower than the highest temperature capable of liquefying DME or carbon dioxide, which will be described later.

Nitrogen produced in the oxygen generator 400 may be used as a refrigerant in the carbon dioxide treatment unit 600 to be described later, may be supplied to the offshore natural gas field 10 to promote the production of natural gas.

The DME production apparatus 300 receives some natural gas from the natural gas production unit 200, produces DME by receiving oxygen from the oxygen generator 400, and a process of producing DME from natural gas is generally known. Description is omitted.

DME floating plant 100 according to the present invention may further include a DME liquefaction apparatus 310, DME storage tank 320.

The DME liquefaction apparatus 310 is installed at the rear end of the DME production apparatus 300, and liquefies the DME produced by the DME production apparatus 300 using a portion of nitrogen produced by the oxygen generator 400 as a refrigerant.

At this time, since the DME liquefies at -25 ° C or less at normal pressure, the nitrogen produced in the oxygen generator, which is a refrigerant of the DME liquefaction apparatus 310, should be able to cool the DME below -25 ° C.

In the DME production apparatus 300, the DME of normal temperature and atmospheric pressure is produced, and the DME becomes a gas phase at normal temperature and normal pressure, so that the DME is a device that liquefies the DME to increase the amount stored in the DME storage tank 320. The liquefaction apparatus 310 may be installed at the rear end of the DME production apparatus 300.

The DME storage tank 320 stores the DME liquefied by the DME liquefaction apparatus, it may be provided in the hull to secure the space of the upper structure of the DME floating plant 100.

The DME stored in the DME storage tank 320 may be transported to a region where the DME is needed by the carrier.

DME floating plant 100 according to the present invention may further include a nitrogen storage tank (450).

Nitrogen storage tank 450 stores the nitrogen produced in the oxygen generator 400, it can be supplied to the place where the nitrogen is a cryogenic inert gas in the DME floating plant.

Nitrogen stored in the nitrogen storage tank 450 is an inert gas, and since there may be many places of use in the DME floating plant, the nitrogen storage tank 450 is installed at the rear of the oxygen generator 400, thereby providing the oxygen generator 400. After storing the nitrogen produced at, it is possible to provide cryogenic nitrogen to each application.

Illustrating the use of nitrogen in the DME floating plant, fire gas for fire suppression, refrigerant gas from the carbon dioxide treatment unit 600 to be described later, offshore natural gas field (10) is supplied to the gas for EGR to promote the production of natural gas, Refrigerant gas to liquefy the DME produced in the DME production apparatus.

Combustion apparatus 500 is produced by supplying some natural gas from the natural gas production unit 200 to produce energy for use in the DME floating plant, for example, a gas turbine that can produce electricity by burning natural gas, A boiler that produces steam, for example.

If the combustion device 500 produces electricity using gas turbines, the electricity produced can be used in the electrical equipment of the DME floating plant. If the boiler is used to produce steam, the produced steam is used for heating in the plant. And so on.

DME floating plant according to the invention may further comprise a waste heat recovery device (550).

The waste heat recovery device 550 recovers the heat of the high-temperature exhaust gas discharged from the combustion device 500, converts the heat into the exhaust gas of normal temperature and atmospheric pressure, and supplies it to the carbon dioxide treatment unit 600.

The exhaust gas discharged after the natural gas is burned in the combustion device 500 includes carbon dioxide, and carbon dioxide is a main culprit of environmental destruction when discharged to the outside, so that the carbon dioxide included in the exhaust gas is provided with a carbon dioxide treatment unit 600 to be described later. Since the exhaust gas is a high temperature, to prevent damage to the mechanical equipment installed in the rear of the combustion device 500, or to recover the heat of the exhaust gas in the rear end of the combustion device 500 for the liquefaction of carbon dioxide to be described later. Waste heat recovery device 550 can be installed.

The carbon dioxide processing unit 600 liquefies carbon dioxide contained in the exhaust gas discharged from the combustion device 500 by using a part of nitrogen produced by the oxygen generator 400 as a refrigerant, and converts the liquefied carbon dioxide into a marine natural gas field 10. To increase the production of natural gas.

As a method of separating carbon dioxide from exhaust gas, a method of capturing carbon dioxide after combustion of fuel may be used. In the present invention, the collected carbon dioxide should be injected into the offshore natural gas field (10) to improve the recovery of natural gas. CO2 is liquefied to obtain a larger amount of carbon dioxide than).

Since liquefied carbon dioxide is reduced in volume, it can store a large amount and stably inject it into the offshore natural gas field 10, thereby increasing the production of natural gas.

The carbon dioxide processor 600 may include a pressurizer 620, a carbon dioxide liquefaction apparatus 630, a liquefied carbon dioxide separator 640, and a liquefied carbon dioxide injector 660.

In order to liquefy the carbon dioxide in the carbon dioxide treatment unit 600, the carbon dioxide should be below the critical temperature (about 31.1 ° C), so the temperature of the exhaust gas is critical

It is necessary to install the apparatus below the temperature in front of the carbon dioxide treatment unit 600, preferably, the waste heat recovery device 550 described above may be installed in front of the carbon dioxide treatment unit 600.

That is, the waste heat recovery device 550 recovers the heat of the exhaust gas to make the exhaust gas temperature less than or equal to about 31.1 ° C. Preferably, the waste heat recovery device 550 is at room temperature (about 15 to 25 ° C.) It is preferable to be supplied to the carbon dioxide treatment unit 600.

The pressurizer 620 pressurizes the exhaust gas above the triple point pressure (about 5.11 atmospheres), which is the minimum pressure at which carbon dioxide can be liquefied, to liquefy the carbon dioxide contained in the exhaust gas passing through the waste heat recovery device 550.

The pressurization range in the pressurizer 620 is preferably pressurized to a pressure near the triple point (about 5.11 atmospheres to 7.5 atmospheres) to minimize energy consumption.

Because carbon dioxide is liquefied only when it reaches about 65 atm at room temperature, it is possible to liquefy at the minimum pressure if the nitrogen produced in the oxygen generator is used as a refrigerant and cooled to the lowest possible temperature for liquefaction. Therefore, the carbon dioxide liquefaction apparatus 630 to be described later will have to cool the carbon dioxide to the lowest temperature at which liquefaction is possible.

The carbon dioxide liquefaction apparatus 630 is installed at the rear of the pressurizer 620 and uses nitrogen produced by the oxygen generator 400 as a refrigerant to liquefy carbon dioxide contained in the exhaust gas passing through the pressurizer 620.

As described above, in order to minimize the energy consumption rate in the pressurizer 620, it is preferable to pressurize to the minimum pressure that can be liquefied (pressure near the triple point). In the carbon dioxide liquefaction device 630, the pressure near the triple point (about 5.11 atm to 7.5 atm) Cool the exhaust gas from -56.4 ° C to -45 ° C.

The arrangement of the pressurizer 620 and the carbon dioxide liquefaction apparatus 630 may be reversed, as illustrated in FIG. 2, but it is preferable to position the carbon dioxide liquefaction apparatus 630 at the rear of the pressurizer 620 for energy saving.

Because, if the carbon dioxide liquefier 630 is located in front of the pressurizer 620, if the pressurizer 620 pressurizes the carbon dioxide cooled to the minimum liquefiable temperature in the carbon dioxide liquefier 630 to liquefy the temperature in the pressurization process As it rises, the pressurizer 620 eventually needs to pressurize as much as the temperature rises for liquefaction, since this causes an increase in energy consumption in the pressurizer 620.

The liquefied carbon dioxide separator 640 may be installed at the rear of the carbon dioxide liquefier 630 to separate the liquefied carbon dioxide produced by the carbon dioxide liquefier 630, and also to separate the liquefied carbon dioxide produced by the pressurizer 620. .

This is because liquefied carbon dioxide may be generated in the pressurizer 620 because carbon dioxide may be liquefied when the exhaust gas at room temperature is pressurized to about 65 atm without passing through the carbon dioxide liquefaction apparatus 630.

The liquefied carbon dioxide injector 660 may inject the liquefied carbon dioxide separated from the liquefied carbon dioxide separator 640 into the offshore natural gas field to facilitate recovery of natural gas.

DME floating plant according to the present invention may further include a liquefied carbon dioxide storage tank (650).

The liquefied carbon dioxide storage tank 650 receives and stores liquefied carbon dioxide separated from the liquefied carbon dioxide separator 660 and supplies liquefied carbon dioxide to the liquefied carbon dioxide injector 660 so that liquefied carbon dioxide can be stably injected into the offshore natural gas field. To help.

DME floating plant according to the invention may further comprise a post-treatment device (610).

The after-treatment device 610 removes impurities from the exhaust gas passing through the waste heat recovery device 550 and supplies them to the pressurizer 620, and removes impurities (sulfur oxide, hydrogen sulfide, etc.) contained in the exhaust gas. If a part of the toxic substance, particulate matter, sulfurous acid gas, etc.) is injected into the offshore natural gas field 10, the offshore natural gas field 10 may be contaminated and other equipment of the carbon dioxide treatment unit 600 may be corroded. .

If the carbon dioxide liquefaction apparatus 630 is disposed in front of the pressurizer 620, the exhaust gas from which impurities are removed from the aftertreatment apparatus 610 will be supplied to the carbon dioxide liquefaction apparatus 630.

The post-treatment device 610 is preferably installed at the rear end of the waste heat recovery device 550 because the post-treatment device 610 can be protected from the high-temperature exhaust gas.

Hereinafter, the operation of the DME floating plant according to the present invention.

DME floating plant according to the present invention is a DME floating plant capable of producing, storing and unloading DME (dimethyl ether), oil and water separated from the mixture after mining the mixture from the offshore natural gas field (10) Are stored in the oil tank 230 and the water tank 240, respectively, and natural gas is supplied to the DME production apparatus to produce DME, which is a clean fuel through reaction with oxygen.

Since the produced DME is a gas at room temperature, it is cooled to about -25 ℃ to make a liquid phase to reduce the volume, stored in the DME storage tank, and supplied to the customer through the carrier.

Therefore, by installing the oxygen generator 400 that can also produce the oxygen required for the production of the refrigerant while producing a refrigerant may produce a DME liquefied with cryogenic nitrogen produced from the oxygen generator 400, by supplying the natural gas field offshore natural It is also possible to enhance the recovery of the gas.

Natural gas obtained from the offshore natural gas field 10 is to produce the energy used in the DME floating plant through the combustion device 500, the exhaust gas discharged from the combustion device 500 through the waste heat recovery device (550) After recovering the waste heat, carbon dioxide, which is the main cause of environmental pollution, should be stored separately.

Liquefied carbon dioxide to increase the storage rate of carbon dioxide, and pressurized to near the triple point pressure of the lowest possible liquefaction pressure in the pressurizer 620 for liquefaction, and the cryogenic nitrogen produced by the oxygen generator 400 in the carbon dioxide liquefier 630 Cool as the refrigerant to the temperature near the triple point (-56.4 ℃ ~ -45 ℃), the lowest liquefiable temperature.

The liquefied carbon dioxide is separated from the liquefied carbon dioxide separator (640), stored in the liquefied carbon dioxide storage tank 650, and injected into the offshore natural gas field (10) by the liquefied carbon dioxide injector (660) to improve the recovery of natural gas. do.

Nitrogen produced in the oxygen generator 400 is also stored in the nitrogen storage tank 450 and used in various demand destinations, the extra nitrogen can be used to enhance the recovery of natural gas by injecting the offshore natural gas field (10). .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

10: offshore natural gas field 100: DME floating plant
200: natural gas production unit 210: three-phase separator
220: pretreatment device 230: oil tank
240: water tank 300: DME production equipment
310: DME liquefaction unit 320: DME storage tank
400: oxygen generator 450: nitrogen storage tank
460: nitrogen injection device 500: combustion device
550: waste heat recovery device 600: carbon dioxide treatment unit
610: post-processing device 620: pressurizer
630: carbon dioxide liquefaction apparatus 640: liquefied carbon dioxide separator
650: liquefied carbon dioxide storage tank 660: liquefied carbon dioxide injector

Claims (13)

In the DME floating plant capable of producing, storing and unloading DME (dimethyl ether),
Natural gas production unit 200 for producing a natural gas by taking a mixture from the offshore natural gas field 10;
An oxygen generator 400 for separating oxygen and nitrogen from air to produce oxygen and nitrogen;
A DME production apparatus 300 receiving some natural gas from the natural gas production unit 200 and receiving oxygen from the oxygen generator 400 to produce a DME;
Combustion apparatus 500 for producing the energy used in the DME floating plant by receiving a portion of natural gas from the natural gas production unit 200 to combust; And
Part of the nitrogen produced in the oxygen generator 400 as a refrigerant to liquefy the carbon dioxide contained in the exhaust gas discharged from the combustion device 500, the liquefied carbon dioxide in the offshore natural gas field (10) A carbon dioxide treatment unit 600 injected into the carbon dioxide to promote production of natural gas;
DME floating plant capable of promoting natural gas production using by-product gas, characterized in that it comprises a. The method according to claim 1,
Supplying a portion of the nitrogen produced by the oxygen generator 400 to the offshore natural gas field 10 to promote the production of natural gas;
DME floating plant capable of promoting natural gas production using by-product gas characterized in that. The method according to claim 1 or 2,
The DME liquefaction apparatus 310 is installed at the rear end of the DME production apparatus 300 to liquefy the DME produced by the DME production apparatus 300 using a portion of nitrogen produced by the oxygen generator 400 as a refrigerant. ; And
A DME storage tank 320 for storing the liquefied DME;
DME floating plant that can increase the production of natural gas using by-product gas, characterized in that it further comprises a. The method according to claim 3,
A nitrogen storage tank 450 for storing nitrogen produced by the oxygen generator 400; further comprising,
Nitrogen stored in the nitrogen storage tank 450 liquefies carbon dioxide in the exhaust gas, liquefies the DME produced in the DME production apparatus, and supplies it to the marine natural gas field 10 to enhance the production of the natural gas. Being;
DME floating plant capable of promoting natural gas production using by-product gas characterized in that. The method according to claim 1,
The natural gas production unit 200,
A three-phase separator 210 separating natural gas, oil and water from the mixture to produce natural gas;
DME floating plant capable of promoting natural gas production using by-product gas, characterized in that it comprises a. The method according to claim 5,
The natural gas production unit 200,
A pretreatment device (220) receiving natural gas from the three-phase separator (210) to remove impurities and supply them to the DME production apparatus (300);
DME floating plant that can increase the production of natural gas using by-product gas, characterized in that it further comprises a. The method according to claim 1,
A waste heat recovery device (550) for recovering heat of the high-temperature exhaust gas discharged from the combustion device (500), converting it into exhaust gas at room temperature and atmospheric pressure, and supplying the exhaust gas to the carbon dioxide processing unit (600);
DME floating plant that can increase the production of natural gas using by-product gas, characterized in that it further comprises a. The method of claim 7,
The carbon dioxide processing unit 600,
A pressurizer 620 for pressurizing above a triple point pressure to liquefy carbon dioxide contained in the exhaust gas passing through the waste heat recovery device 550;
A carbon dioxide liquefaction apparatus (630) installed at a rear end of the pressurizer (620) and using nitrogen produced in the oxygen generator (400) as a refrigerant to liquefy carbon dioxide contained in the exhaust gas passing through the pressurizer (620);
A liquefied carbon dioxide separator (640) installed at a rear end of the carbon dioxide liquefier (630) to separate the liquefied carbon dioxide produced by the pressurizer (620) or the carbon dioxide liquefier (630); And
A liquefied carbon dioxide injector (660) for injecting the separated liquefied carbon dioxide into the natural gas field (10);
DME floating plant capable of promoting natural gas production using by-product gas, characterized in that it comprises a. The method according to claim 8,
A liquefied carbon dioxide storage tank 650 for receiving and storing liquefied carbon dioxide separated from the liquefied carbon dioxide separator 660 and supplying liquefied carbon dioxide to the liquefied carbon dioxide injector 660;
DME floating plant that can increase the production of natural gas using by-product gas, characterized in that it further comprises a. The method according to claim 8 or 9,
The carbon dioxide processing unit 600,
A post-treatment device 610 which removes impurities from the exhaust gas passing through the waste heat recovery device 550 and supplies them to the pressurizer 620;
DME floating plant that can increase the production of natural gas using by-product gas, characterized in that it further comprises a. delete delete delete

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