KR101479486B1 - Lng regasification real-time operating system and operating method - Google Patents

Abstract

Provided is an LNG regasification real-time operating system of a floating structure (100), comprising an LNG storage tank (130) to supply LNG to a suction drum (140) for the LNG regasification real-time automatic operating system of the floating structure (100): a compressor (120), which supplies BOG to the suction drum; a low pressure pump located in the suction drum (140) for supplying LNG mixed with BOG toward a high pressure pump (160); the high pressure pump (160), which compresses and supplies the LNG mixed with BOG in order to supply the LNG to a carburetor (180); a sea water pump (170), which supplies sea water to the carburetor (180) in order to help evaporation; the carburetor (180), which evaporates the LNG mixed with BOG, using the thermal energy of sea water; and a ship automatic control device (110), which determines the operation number of each structure.

Description

{LNG REGASIFICATION REAL-TIME OPERATING SYSTEM AND OPERATING METHOD}

The present invention relates to a regeneration system for an LNG carrier, and more particularly to an optimized operating system and method for automatically controlling each component in real time on a regeneration system of an LNG.

The demand for natural gas has increased sharply worldwide, and the production, supply and transport of natural gas is connected to the competitiveness of the nation.

In countries where natural gas is not produced, land pipelines are connected from neighboring countries to import natural gas or import LNG using transport lines. Transport LNG is stored in a liquefied storage tank on the shore and regenerated according to the conditions such as pressure, flow rate and temperature according to the demand of the customer.

However, such onshore LNG storage is suitable for areas with stable LNG demand, but there are economic disadvantages such as high installation costs and maintenance costs when there is temporary or seasonal demand. On the other hand, land-based LNG regasification facilities are at risk of being problematic due to terrorism and natural disasters.

Accordingly, recently, LNG-RV (Korean Patent Application No. 10-2006-0045018, LNG carrier to natural gas supply method from natural gas to LNG carrier and method of supplying natural gas to LNG carrier) LNG FSRU (domestic patent application No. 10-2007-0085870, LNG (LNG)) which supplies LNG regenerated from the sea directly to the demand of the land by using floating structure (100) equipped with storage and regeneration facilities of LNG Floating storage regeneration facilities) are being developed.

LNG-RV is the addition of LNG regeneration function to LNG carrier that can navigate and float on its own. LNG FSRU is supplied LNG from LNG carrier in off-shore area and stores it. Supply.

The regeneration of the LNG is performed by supplying LNG to the vaporizer at a high pressure in the storage tank. At this time, equipment necessary for regeneration such as high pressure pump, vaporizer, and seawater pump is used. Up to now, there has not been provided a system for automatically regulating the number of regenerating equipment related to the usage amount of LNG.

Therefore, the operator of the LNG-RV or LNG FSRU has a problem in optimizing the operation of the regasification.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-mentioned problems, and provides a method of optimizing operation of LNG regasification supplied from a floating structure having a regeneration function to a demand site on the land. In other words, it is aimed to monitor the regeneration facilities in real time, and to provide optimized operation by driving the required number of equipments.

The advantage of this operation is that it can be controlled by an automated system to preclude the intervention of an operator's artificial effort.

According to an aspect of the present invention, there is provided a method for real-time operating LNG regasification of a floating structure, the method comprising: determining an LNG regasification feed rate; Automatically determining the operation number of the vaporizer corresponding to the LNG regasification supply amount; Automatically determining the number of operations of the seawater pump corresponding to the number of carburetor operations; Automatically determining the number of operations of the high-pressure pump corresponding to the number of carburetor operations; And automatically determining the number of operations of the low-pressure pump in the LNG storage tank corresponding to the number of operations of the high-pressure pump.

According to one embodiment, the LNG regasification real-time operating method of the floating structure includes automatically determining the number of operations of the BOG compressor that supplies the BOG corresponding to the LNG feed amount supplied to the suction drum .

According to one embodiment, the step of automatically determining the number of operations of the vaporizer includes the step of automatically determining the number of operations of the vaporizer by the ship automatic control device after comparing the vaporizable capacity of the vaporizer with the LNG regeneration supply amount do.

According to one embodiment, the step of automatically determining the number of operations of the seawater pump includes automatically determining the number of operations of the seawater pump by the ship automatic control device according to the required amount of seawater of the vaporizer.

According to one embodiment, the step of automatically determining the number of operations of the high-pressure pump includes automatically determining the number of operations of the high-pressure pump by the ship automatic control device according to the LNG requirement of the vaporizer.

According to one embodiment, the step of automatically determining the number of operations of the low-pressure pump in the LNG storage tank includes automatically determining the number of operations of the low-pressure pump by the ship automatic control device according to the LNG requirement of the high-pressure pump .

According to one embodiment, determining the regasification feed rate includes setting a daily LNG feed requirement at the consumer.

According to one embodiment, the LNG regasification real-time operating method includes a step of real-time resetting the daily LNG supply demand at the demanding site.

According to another aspect of the present invention, there is provided a real-time operating system for LNG regasification of a floating structure, comprising: a low pressure pump in an LNG storage tank for supplying LNG to a suction drum; A suction drum for supplying the LNG to the high-pressure pump; A high pressure pump for compressing and supplying LNG to the vaporizer; A seawater pump for supplying seawater to the vaporizer to assist vaporization; A vaporizer for vaporizing LNG using thermal energy of seawater; Low-pressure pumps, high-pressure pumps, seawater pumps, and ship automatic controls to determine the number of carburetor operations.

According to one embodiment, the LNG regasification real-time operating system further includes a BOG compressor that supplies BOG to the suction drum.

According to one embodiment, the ship automatic control device automatically determines the number of operations of the BOG compressor in accordance with the amount of LNG supplied to the suction drum.

According to one embodiment, the ship automatic control system automatically determines the number of operation of the low-pressure pump in accordance with the LNG requirement of the high-pressure pump, and provides a real-time operating system for LNG regeneration of the floating structure.

According to one embodiment, the ship automatic control device automatically determines the number of operations of the high-pressure pump in accordance with the LNG requirement of the vaporizer.

According to one embodiment, the ship automatic control device automatically determines the operation number of the seawater pump according to the required amount of seawater of the vaporizer.

According to one embodiment, the ship automatic control device automatically determines the operation number of the vaporizer by comparing the vaporizable capacity of the vaporizer with the LNG regeneration supply amount.

Previously, the operator manually changed the number of operations of low pressure pump, high pressure pump, BOG compressor, seawater pump and carburetor for daily requirement of LNG regeneration. The LNG regeneration real-time operating system can automatically perform the optimization operation because it controls the start / stop part of the regeneration system automatically.

1 is a block diagram of a real-time operating system for LNG regasification of a floating structure.
2 is an operational flow diagram of a method for real-time operating LNG regasification of a floating structure.
3 is a conceptual diagram of a real-time operating system for LNG regasification of a floating structure.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the preferred embodiments of the present invention will be described below, but it is needless to say that the technical idea of the present invention is not limited thereto and can be variously modified by those skilled in the art.

1 is a block diagram of a real-time operating system for LNG regasification of a floating structure 100 having a regeneration facility such as an LNGC-RV / FSRU vessel.

1, the floating structure 100 includes an LNG storage tank 130, a suction drum 140, a high pressure pump 160, a vaporizer 180, a seawater pump 170, a BOG compressor 120, And an automatic vessel control device 110.

The floating structure 100 shown in the drawings may be any vessel or structure capable of being moored in the sea with a regeneration facility therein.

The LNG storage tank 130 is a space for storing liquefied natural gas, and is connected to the suction drum 140. The LNG storage tank 130 includes a low-pressure pump 150 therein.

The suction drum 140 is connected to the LNG storage tank 130, the BOG compressor 120 and the high-pressure pump 160. The suction drum 140 receives LNG from the LNG storage tank 130 and receives BOG from the BOG compressor 120. The suction drum 140 mixes the low pressure BOG with the LNG to aid vaporization of the LNG. LNG mixed with BOG has high vaporization efficiency.

The suction drum 140 is connected to the high-pressure pump 160 and supplies LNG mixed with BOG to the high-pressure pump 160 as a connected control valve and gravity. The operation number of the low pressure pump 150 is determined by the ship automatic control device 110.

The high-pressure pump 160 is connected to the suction drum 140 and the vaporizer 180. The high pressure pump 160 compresses and supplies the LNG mixed with the BOG supplied from the suction drum 140 to the vaporizer 180. The operation of the high pressure pump 160 is controlled by the ship automatic control device 110 in order to adjust the amount of the BOG mixed LNG supplied to the vaporizer 180.

The seawater pump 170 is connected to the vaporizer 180 and supplies the thermal energy of the seawater to the vaporizer 180 to help the vaporizer 180 vaporize the LNG. The seawater pump 170 determines the number of operations by the ship automatic control device 110 in order to adjust the supply of seawater.

The vaporizer 180 is connected to the seawater pump 170, the high-pressure pump 160 and the on-land LNG consumer 190. The high-pressure pump 160 compresses the LNG mixed with the BOG to facilitate vaporization, and then supplies the LNG to the vaporizer 180. At this time, the LNG supplied to the vaporizer 180 maintains a liquid state at a temperature of minus -160 degrees Celsius. Such LNG absorbs thermal energy of the sea water to vaporize and is vaporized into a gaseous state.

This vaporized natural gas is supplied via a pipe to the LNG demand site 190 on the land. In order to adjust the LNG supply amount, the operation number of the vaporizer 180 is determined by the ship automatic control device 110. The number of units of each of these equipment is automatically controlled to meet the LNG requirements required by the onshore demand.

The ship automatic control apparatus 110 is an apparatus for automatically controlling the LNG re-generation real time operating system of the floating structure 100. The automatic vessel control system 110 is connected to the BOG compressor 120, the low pressure pump 150, the high pressure pump 160, the seawater pump 170 and the vaporizer 180 to control the respective operation numbers.

The ship automatic control device 110 can be operated in a fully automated mode and a semi-automated mode. In the full automatic mode, the number of operations of the BOG compressor 120, the low-pressure pump 150, the high-pressure pump 160, the seawater pump 170, and the vaporizer 180 is automatically controlled in real- . The semi-automatic mode sets the number of operations of the BOG compressor 120, the low-pressure pump 150, the high-pressure pump 160, the seawater pump 170, and the vaporizer 180 by the operator and performs the LNG regeneration.

2 is an operational flow diagram of a method for real-time operating the LNG regasification of the floating structure 100. FIG.

For LNG regasification, the operator determines the amount of LNG regasification (200).

The ship automatic control device 110 determines the number of operations of the appropriate vaporizer 180 in accordance with the determined LNG regeneration supply amount (202). At this time, the LNG regasification supply amount to be supplied is compared with the LNG receivable amount of the vaporizer 180 whose operation is determined (204). If the LNG regasification supply amount is equal to the LNG receivable total amount of the vaporizer 180, the procedure goes to the step of determining the operation number of the seawater pump 170, and if not, the operation returns to the step of determining the operation number of the vaporizer 180 again.

The ship automatic control device 110 determines the number of operations of the seawater pump 170 for supplying seawater to the vaporizer 180 (206). At this time, the required amount of seawater of the vaporizer 180 is compared with the available amount of the seawater supplyable amount of the determined seawater pump 170 (208). If the required amount of seawater of the carburetor 180 is equal to the total amount of the seawater supplyable amount of the determined seawater pump 170, the procedure goes to the step of determining the number of operations of the high-pressure pump 160, Return to step.

The ship automatic control apparatus 110 determines the number of operations of the high-pressure pump 160 supplying the compressed LNG to the vaporizer 180 (210). At this time, the LNG demand amount of the vaporizer 180 is compared with the LNG supply amount of the high-pressure pump 160 (212). If the LNG requirement of the carburetor 180 is equal to the total LNG supply amount of the determined high-pressure pump 160, the process proceeds to the step of determining the number of operations of the low-pressure pump 150, Return to step.

The ship automatic control unit 110 determines the number of operations of the low-pressure pump 150 in the LNG storage tank 130 (214). At this time, the LNG demand amount of the high-pressure pump 160 is compared with the LNG supply amount of the low-pressure pump 150 (216). If the LNG requirement of the high-pressure pump 160 is equal to the total amount of the LNG supplyable amount of the low-pressure pump 150, the process proceeds to the step of determining the number of operations of the BOG compressor 120, Return to step.

3 is a conceptual diagram of the LNG regasification real-time operating system of the floating structure 100. FIG. As described above, the LNG regeneration real-time operating system of the floating structure 100 includes the LNG storage tank 130, the suction drum 140, the low-pressure pump 150, the high-pressure pump 160, Vaporizer 180, seawater pump 170,. And an automatic vessel control system 110.

The ship automatic control apparatus 110 determines the number of operations of the low pressure pump 150, the BOG compressor 120, the high pressure pump 160, the seawater pump 170, and the vaporizer 180. Each configuration operates in duty and standby. Duty refers to each configuration determined to be operated, and a configuration determined to be standby is operated in place when a situation in which the configurations determined by the duty can not be operated.

The LNG regasification supply amount is determined on a daily basis. After the supply amount is determined, the user 192 can set a new supply amount to change the operation of each configuration. (Feed Forward)

Claims (15)

In the real-time operating method of the LNG regasification of the floating structure 100,
Determining an LNG regasification feed rate;
Automatically determining an operation number of the vaporizer corresponding to the LNG regeneration supply amount;
Automatically determining the operation number of the seawater pump in accordance with the number of carburetor operations;
Automatically determining the number of operations of the high-pressure pump corresponding to the number of carburetor operations; And
And automatically determining the number of operations of the low-pressure pump in the LNG storage tank in accordance with the number of operations of the high-pressure pump,
The method for real-time operating the LNG regeneration of the floating structure may further include automatically determining the number of operations of the BOG compressor for supplying BOG in correspondence with the amount of LNG supplied to the suction drum Real - Time Operation Method of LNG Regasification of Floating Structures. delete In the real-time operating method of the LNG regasification of the floating structure 100,
Determining an LNG regasification feed rate;
Automatically determining an operation number of the vaporizer corresponding to the LNG regeneration supply amount;
Automatically determining the operation number of the seawater pump in accordance with the number of carburetor operations;
Automatically determining the number of operations of the high-pressure pump corresponding to the number of carburetor operations; And
And automatically determining the number of operations of the low-pressure pump in the LNG storage tank in accordance with the number of operations of the high-pressure pump,
The step of automatically determining the number of operations of the vaporizer may further include the step of automatically determining the number of operations of the vaporizer by the ship automatic control device after comparing the vaporizable capacity of the vaporizer with the LNG regeneration supply amount Wherein the LNG regeneration is performed at a predetermined temperature. In the real-time operating method of the LNG regasification of the floating structure 100,
Determining an LNG regasification feed rate;
Automatically determining an operation number of the vaporizer corresponding to the LNG regeneration supply amount;
Automatically determining the operation number of the seawater pump in accordance with the number of carburetor operations;
Automatically determining the number of operations of the high-pressure pump corresponding to the number of carburetor operations; And
And automatically determining the number of operations of the low-pressure pump in the LNG storage tank in accordance with the number of operations of the high-pressure pump,
Wherein the step of automatically determining the operation number of the seawater pump includes automatically determining the operation number of the seawater pump by the ship automatic control device according to the required amount of seawater of the vaporizer Real - time operation method of LNG regasification. In the real-time operating method of the LNG regasification of the floating structure 100,
Determining an LNG regasification feed rate;
Automatically determining an operation number of the vaporizer corresponding to the LNG regeneration supply amount;
Automatically determining the operation number of the seawater pump in accordance with the number of carburetor operations;
Automatically determining the number of operations of the high-pressure pump corresponding to the number of carburetor operations; And
And automatically determining the number of operations of the low-pressure pump in the LNG storage tank in accordance with the number of operations of the high-pressure pump,
Wherein the step of automatically determining the number of operations of the high-pressure pump includes automatically determining the number of operations of the high-pressure pump by the ship automatic control device in accordance with the LNG requirement of the vaporizer. Real - time operation method of LNG regasification. In the real-time operating method of the LNG regasification of the floating structure 100,
Determining an LNG regasification feed rate;
Automatically determining an operation number of the vaporizer corresponding to the LNG regeneration supply amount;
Automatically determining the operation number of the seawater pump in accordance with the number of carburetor operations;
Automatically determining the number of operations of the high-pressure pump corresponding to the number of carburetor operations; And
And automatically determining the number of operations of the low-pressure pump in the LNG storage tank in accordance with the number of operations of the high-pressure pump,
The step of automatically determining the number of operations of the low-pressure pump in the LNG storage tank may include the step of automatically determining the number of operations of the low-pressure pump by the ship automatic control device according to the LNG demand amount of the high-pressure pump LNG regasification real - time operating method of floating structure. In the real-time operating method of the LNG regasification of the floating structure 100,
Determining an LNG regasification feed rate;
Automatically determining an operation number of the vaporizer corresponding to the LNG regeneration supply amount;
Automatically determining the operation number of the seawater pump in accordance with the number of carburetor operations;
Automatically determining the number of operations of the high-pressure pump corresponding to the number of carburetor operations; And
And automatically determining the number of operations of the low-pressure pump in the LNG storage tank in accordance with the number of operations of the high-pressure pump,
Wherein the step of determining the regasification supply amount includes a step of setting a daily LNG supply demand amount at a customer. The method of claim 7,
Wherein the LNG regasification real-time operating method comprises the step of real-time resetting the daily LNG supply demand amount at the demanding entity. In a real-time operating system for LNG regasification of a floating structure,
A low pressure pump in an LNG storage tank for supplying LNG to a suction drum;
A suction drum for supplying the LNG to the high-pressure pump;
A high pressure pump for compressing and supplying the LNG to the vaporizer;
A seawater pump for supplying seawater to the vaporizer to assist vaporization;
A vaporizer for vaporizing the LNG using thermal energy of the seawater; And
Pressure pump, a seawater pump, and a carburetor, wherein the low-pressure pump, the high-pressure pump, the seawater pump,
Further comprising a BOG compressor for supplying BOG to the suction drum. delete The method of claim 9,
Wherein the automatic ship control system automatically determines the number of operations of the BOG compressor according to an amount of LNG supplied to the suction drum. In a real-time operating system for LNG regasification of a floating structure,
A low pressure pump in an LNG storage tank for supplying LNG to a suction drum;
A suction drum for supplying the LNG to the high-pressure pump;
A high pressure pump for compressing and supplying the LNG to the vaporizer;
A seawater pump for supplying seawater to the vaporizer to assist vaporization;
A vaporizer for vaporizing the LNG using thermal energy of the seawater; And
Pressure pump, a seawater pump, and a carburetor, wherein the low-pressure pump, the high-pressure pump, the seawater pump,
Wherein the ship automatic control apparatus automatically determines an operation number of the high pressure pump in accordance with an LNG demand amount of the vaporizer. In a real-time operating system for LNG regasification of a floating structure,
A low pressure pump in an LNG storage tank for supplying LNG to a suction drum;
A suction drum for supplying the LNG to the high-pressure pump;
A high pressure pump for compressing and supplying the LNG to the vaporizer;
A seawater pump for supplying seawater to the vaporizer to assist vaporization;
A vaporizer for vaporizing the LNG using thermal energy of the seawater; And
Pressure pump, a seawater pump, and a carburetor, wherein the low-pressure pump, the high-pressure pump, the seawater pump,
Wherein the ship automatic control apparatus automatically determines an operation number of the high pressure pump in accordance with an LNG demand amount of the vaporizer. In a real-time operating system for LNG regasification of a floating structure,
A low pressure pump in an LNG storage tank for supplying LNG to a suction drum;
A suction drum for supplying the LNG to the high-pressure pump;
A high pressure pump for compressing and supplying the LNG to the vaporizer;
A seawater pump for supplying seawater to the vaporizer to assist vaporization;
A vaporizer for vaporizing the LNG using thermal energy of the seawater; And
Pressure pump, a seawater pump, and a carburetor, wherein the low-pressure pump, the high-pressure pump, the seawater pump,
Wherein the automatic ship control system automatically determines the number of seawater pumps operated according to the required amount of seawater of the vaporizer. In a real-time operating system for LNG regasification of a floating structure,
A low pressure pump in an LNG storage tank for supplying LNG to a suction drum;
A suction drum for supplying the LNG to the high-pressure pump;
A high pressure pump for compressing and supplying the LNG to the vaporizer;
A seawater pump for supplying seawater to the vaporizer to assist vaporization;
A vaporizer for vaporizing the LNG using thermal energy of the seawater; And
Pressure pump, a seawater pump, and a carburetor, wherein the low-pressure pump, the high-pressure pump, the seawater pump,
Wherein the ship automatic control apparatus automatically determines the number of operations of the vaporizer by comparing the vaporizable capacity of the vaporizer with the LNG regeneration supply amount.

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