KR20130006055A - Hydrate inhibitor feed system for dme fpso - Google Patents

Abstract

PURPOSE: A hydrate inhibitor feeding system for a DME FPSO(Dimetyle Ether Floating Production Storage And Offloading) is provided to efficiently utilize the limited space of the DME FPSO because additional tank and recycling system are not necessary by recycling by-products. CONSTITUTION: A hydrate inhibitor feeding system for a DME FPSO comprises a 3-phase separator(11), a preprocessing device(14), a modifying reactor(15), a DME reactor(16), and a DME separator(17). The 3-phase separator separates natural gas supplied from a seabed gas field through a pipeline. The preprocessing device preprocesses separated byproduct gas. The modifying reactor modifies the preprocessed byproduct gas and synthesizes the modified byproducts gas to synthetic gas. The DME reactor products the synthetic gas to DME. The DME separator separates pure DME. [Reference numerals] (AA) Natural gas

Description

Hydrate inhibitor feed system for DME FPSO}

The present invention relates to a hydrate inhibitor supply system for DME FPSO, and more particularly, to supply a hydrate inhibitor for DME FPSO, which can reduce the cost used for hydrate inhibition by recycling methanol produced as a by-product from DME FPSO as a hydrate inhibitor. It is about the system.

Floating Production Storage and offloading (FPSO) is a floating offshore structure that simultaneously produces, stores and unloads crude oil or natural gas. There is no limit on the operating depth, but it is economical in the deep sea and the maximum operating depth reaches 1,853m.

Among these FPSOs, DME FPSO is a facility for producing DME (dimethyl ether, dimethyl ether) using natural gas.

The DME FPSO supplies natural gas to the DME production system 200 through the pipeline 100 from the gas well (Gas), as shown in Figure 2, the natural gas is predetermined in the DME production system 200 The DME is produced through the process of the produced DME is stored in the storage tank 210.

On the other hand, natural gas contains water, which exists as a hydrate in the gas field due to the high pressure of the gas field. Therefore, when gas is supplied through the pipeline, solid hydrate may rise along the supply and may damage or corrode by hitting the inner circumferential surface of the pipeline, and in severe cases, the pipeline or gas field may be blocked and generate a large accident. Could.

Therefore, conventionally, hydrate inhibitors are injected into the gas field through a chemical pipeline to suppress the formation of hydrates.

The typical representative hydrate inhibitors are methanol and monoethylene glycol (MEG).

When methanol is used as a hydrate inhibitor of gas field, there is a problem in that a methanol tank 300 must be separately provided in FPSO as shown in FIG. 2. In addition, since the methanol is difficult to be separated after the dehydration reaction, the methanol supply line 400 for supplying methanol had to be periodically operated, thereby increasing the DME manufacturing cost.

Another hydrate inhibitor, MEG, has a strong hydrophilicity that absorbs moisture, and more than 90% of the added MEG can be recovered from onshore facilities, making it more economical to use than methanol. Nevertheless, it is widely used because it does not require continuous operation of supply lines.

However, MEG also has a disadvantage of securing space in the DME FPSO, which has a space limitation because it is difficult to recover unless a separate solvent regeneration system as shown in FIG. 3 is provided in the FPSO.

The present invention is to solve the above problems,

It is an object of the present invention to provide a hydrate inhibitor supply system of DME FPSO, which can be supplied with a hydrate inhibitor used in a gas field dehydration process without a separate methanol supply line or a regeneration system for recovering MEG.

Another object of the present invention is to more economically prevent hydrate formation in gas fields.

The present invention to achieve the above object,

It provides a hydrate inhibitor supply system for DME FPSO, characterized in that to recover the methanol by-product produced in the DME synthesis process for producing natural gas to DME to use as a hydrate inhibitor of the gas field.

In addition, the DME produced in the DME synthesis process is stored in the DME storage tank,

Methanol is distilled through a dehydration column and then recovered and stored in a methanol storage tank.

Methanol of the methanol storage tank is characterized in that supplied to the gas field.

In addition, the methanol storage tank is characterized in that the chemical tank provided in the FPSO.

In addition, the methanol of the methanol storage tank is characterized in that it is supplied to the gas field through the riser system.

In addition, the riser system includes a flexible pipe and a coupler provided at both ends of the flexible pipe,

The coupler is characterized in that connecting both ends of the flexible pipe to the connector of the buoy connecting the end pipe and the riser of the methanol storage tank, respectively.

In addition, the DME synthesis process is a three-phase separator for separating the natural gas supplied through the pipeline in the subsea gas field into water, oil and by-product gas;

A pretreatment device for pretreating the separated by-product gas;

A reforming reactor for reforming the pretreated by-product gas and synthesizing it into syngas;

A DME reactor for producing syngas as DME;

It characterized in that it comprises a DME separation process for separating only pure DME.

As described above, the hydrate inhibitor supply system for DME FPSO according to the present invention does not require periodic operation of the methanol supply line for methanol supply because methanol for preventing hydrate formation in gas field is generated in DME FPSO itself. This can be reduced, and by recycling the by-products do not require a separate tank or the regeneration system required in the conventional MEG, there is an effect that can effectively utilize the limited space of the DME FPSO.

In addition, since the general chemical tank provided in the DME FPSO can be used as it is, as well as saving space, the cost used for hydrate suppression can be further reduced, thereby having an economic effect.

1 is a conceptual diagram showing a hydrate inhibitor supply system for DME FPSO according to an embodiment of the present invention.
Figure 2 is a conceptual diagram showing an example of a hydrate inhibitor supply system of the conventional FPSO.
3 is a conceptual diagram showing a general playback system of MEG.

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited to the embodiments shown in the drawings.

1 is a conceptual diagram showing a hydrate inhibitor supply system for DME FPSO according to an embodiment of the present invention.

As shown therein, the present invention provides a hydrate inhibitor for DME FPSO, which is used as a hydrate inhibitor of gas field by recovering methanol, which is a byproduct produced in the DME synthesis process 10, which produces natural gas as DME (dimethylether). The present invention relates to a system, which requires a separate methanol supply line because methanol is recovered and used, or does not require a separate solvent regeneration system to recover a hydrate inhibitor.

Here, the DME synthesis process 10 includes a three phase separator 11, a pretreatment device 14, a reforming reactor 15, a DME reactor 16, and a DME separation process 17, and a three phase separator 3 In the -phase separator (11), the natural gas supplied through the pipeline 100 in the gas well is separated into water, condensate and by-product gas. At this time, the by-product gas is gasified according to the pressure conditions are separated from the liquid and separated, water and oil can be separated using the difference in specific gravity.

The separated water and oil are transferred to and stored in the water reservoir 12 and the oil reservoir 13, respectively, in order to prevent environmental pollution, and the water stored in the water reservoir 12 is discharged through a water treatment system or purged. It is used as water for the process.

The pretreatment device 14 is a device for removing components such as sulfur, mercury, and CO ₂ contained in the separated by-product gas, and the by-product gas supplied from the three-phase separator is transferred to the pretreatment device 14 such a pretreatment. Is done.

The reforming reactor 15 is a device for reforming the pretreated by-product gas and synthesizing the synthesis gas, and the reforming reactor 15 produces syngas (H ₂ , CO) through a reforming reaction.

The reforming reaction includes steam reforming (SRM, Steam Reforming of Methane), carbon dioxide reforming (CDR, Carbon Dioxide Reforming of Methane), autothermal reforming (ATR, Auto-Thermal Reforming), partial oxidation (POX, Partial Oxidation of Methane) This can be used.

The DME reactor 16 is a device for producing the syngas produced as described above as DME, which is synthesized as DME through a reaction as in Scheme 1 below, wherein methanol (CH ₃ OH) is produced as a by-product.

[Reaction Scheme 1]

The DME separation process 17 is to separate only pure DME from Crude-DME containing CO ₂ , methanol, and water generated in the DME reactor 10, and includes a low-purity DME containing various impurities. Purification through the refining method to be separated into a high purity DME, the separated DME is transferred to the DME storage tank 20 through a transfer pipe and stored.

Here, as an example of the DME separation process, a purification method using a cooling method may be used. It cools the synthesized gas in the DME reactor and then separates the gas-liquid separation. The unreacted syngas coming out of the gas phase is regenerated to the front of the DME reactor, and the CO ₂ , DME, methanol, and water coming out of the liquid phase are transferred to the CO ₂ column. send. In the CO ₂ column, pure CO ₂ is discharged to the top of the CO ₂ column, and at the bottom, a liquid phase consisting of methanol, DME, and water is discharged, which is then sent to the DME column, where the DME is gaseous, and methanol and water are purified in a liquid state. Only DME can be obtained. However, the cooling method is only one example of the DME separation process, and the DME separation process is not limited to the above-described cooling method.

The DME produced in the DME synthesis process as described above is stored in the DME storage tank 20 through the transfer pipe as described above. Methanol, which is a by-product produced in the DME synthesis process, is distilled through a dehydration distillation column (30) and then recovered into a methanol storage tank (40).

At this time, the methanol is distilled to remove a small amount of water contained in the methanol produced in the DME synthesis process.

In addition, the methanol storage tank 40 can use a general chemical tank provided in the FPSO itself, methanol is in a liquid state at room temperature, atmospheric pressure, and there is no rubber corrosion, so the sealing parts of the storage tank other than rubber There is no need to replace the material, and no separate liquefaction equipment is required, so any tank surface capable of storing common chemicals such as methanol in the FPSO can be used.

Therefore, since there is no need to provide a separate storage tank, the cost is reduced and economical, and it is possible to use the space of the FPSO more efficiently since there is no need to construct a separate facility such as a conventional MEG regeneration system.

In addition, the methanol of the methanol storage tank 40 is supplied to the gas field to prevent hydrate formation. Methanol of the methanol storage tank 40 is supplied to the gas field safely through a riser system (Riser system).

The riser system 50 connects a methanol storage tank 40 of FPSO and a gas field to the riser 70 to supply methanol, and the riser system 50 is provided at both ends of the soft pipe 52 and the soft pipe 52. It includes a coupler (51) (53) provided, connecting the both ends of the flexible pipe (52) through the coupler (51, 53), respectively, the end pipe (41) and riser (70) of the methanol storage tank (40) It is connected to the connector 61 of the buoy 60 to supply methanol to the gas field.

That is, methanol in the methanol storage tank 40 is supplied to the buoy via the riser system 50 and the connector, and methanol supplied to the buoy is supplied to the gas field through the riser to prevent hydrate formation. In this case, the riser is preferably manufactured to be flexible to accommodate the shaking of the FPSO.

The hydrate inhibitor supply system for DME FPSO according to the present invention having the above configuration does not require periodic operation of the methanol supply line for methanol supply because methanol for preventing hydrate formation in gas fields is generated in DME FPSO itself. The operating costs can be reduced and economical, and by-products are recycled, thus eliminating the need for a separate tank or facility, thereby effectively utilizing the limited space of the DME FPSO.

In addition, by effectively preventing the formation of hydrate in the gas field, it is possible to reduce the major accident by preventing the progress or blockage of corrosion of the pipeline due to the hydrate generation.

10: DME synthesis process 11: three phase separator
12: water reservoir 13: oil reservoir
14: pretreatment device 15: reforming reactor
16: DME Reactor 17: DME Separation Process
20: DME storage tank 30: dewatering distillation column
40: methanol storage tank 41: end pipe
50: riser system 51, 53: coupler
52: soft piping 60: buoy
61: connector 70: riser

Claims (6)

A hydrate inhibitor supply system for DME FPSO, characterized by recovering methanol, a byproduct produced in the DME synthesis process (10), which produces natural gas as a DME, and using it as a hydrate inhibitor in gas field. The method according to claim 1,
DME produced in the DME synthesis process 10 is stored in the DME storage tank 20,
Methanol is distilled through a dehydration distillation column (30) and then recovered and stored in a methanol storage tank (40).
A hydrate inhibitor supply system for DME FPSO, characterized in that the methanol of the methanol storage tank 40 is supplied to the gas field. The method according to claim 2,
The methanol storage tank 40 is a hydrate inhibitor supply system for DME FPSO, characterized in that the chemical tank provided in the FPSO. The method according to claim 2,
The hydrate inhibitor supply system for DME FPSO, characterized in that the methanol of the methanol storage tank is supplied to the gas field through the riser system. The method of claim 4,
The riser system 50 includes a soft pipe 52 and couplers 51 and 53 provided at both ends of the soft pipe 52.
The couplers 51 and 53 connect both ends of the soft pipe 52 to the connector 63 of the buoy 60 connecting the end pipe 41 and the riser 70 of the methanol storage tank 40, respectively. A hydrate inhibitor supply system for DME FPSO, characterized in that. The method according to any one of claims 1 to 5,
The DME synthesis process 10 includes a three-phase separator 11 for separating natural gas supplied through a pipeline in a subsea gas field into water, oil and by-product gas;
A pretreatment device 14 for pretreating the separated by-product gas;
A reforming reactor (15) for reforming the pretreated by-product gas and synthesizing it into syngas;
A DME reactor 16 for producing syngas into DME;
A hydrate inhibitor supply system for DME FPSO, comprising a DME separation process (17) for separating only pure DME.

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