KR101586118B1 - A Treatment System and Method Of Liquefied Natural Gas - Google Patents

Abstract

The present invention relates to an LNG treatment system, comprising: a sea water line connecting a seawater pump and an LNG heat exchanger and discharging seawater to the outside; A seawater pump provided on the sea water line for supplying seawater to the LNG heat exchanger; An LNG heat exchanger provided on the sea water line for exchanging heat with seawater to the LNG; A chemical supply line connecting the chemical storage tank and the seawater pump or the seawater line; And a water supply line provided on the chemical supply line, connected between the chemical storage tank and the seawater pump, for supplying chemical when the heating of the LNG stops, and when the chemical cleaning process is stopped And a chemical pump that stops chemical supply.
The present invention also relates to a method for treating an LNG treatment system comprising a seawater pump for supplying seawater to an LNG heat exchanger, a purifier, a chemical tank, a chemical pump, and a chemical measuring device, Supplying seawater to the LNG heat exchanger using a seawater pump; Exchanging heat between seawater and LNG in the LNG heat exchanger; Discharging seawater to the outside in the LNG heat exchanger; Stopping the inflow of seawater into the seawater pump when the heating process of the LNG is stopped; Supplying the chemical from the chemical tank to the seawater pump or the seawater line using the chemical pump; Cleaning the seawater line using chemicals; And a chemical measuring device for measuring the concentration of the chemical substance in the chemical solution when the difference between the concentration of the chemical substance measured by the chemical measuring device and the chemical is within a predetermined value range for the fluid flowing on the seawater line, And stopping the supply.
The LNG treatment system and method according to the present invention is characterized in that LNG heating is performed by flushing and cleaning the apparatus or equipment constituting the LNG heating by using the fresh water pump, fresh water tank, chemical water pump and chemical tank after LNG heating Corrosion and erosion of the apparatus or equipment constituting the structure of the present invention can be prevented, and durability can be increased to prolong the service life of the equipment, so that the operating efficiency can be improved.

Description

Technical Field [0001] The present invention relates to a LNG treatment system,

The present invention relates to a LNG processing system and method.

Generally, it is known that LNG is a clean fuel and its reserves are more abundant than petroleum, and its usage is rapidly increasing as mining and transfer technology develops. This LNG is generally stored in a liquid state at a temperature of -162 ° C or less under 1 atm of the main component. The volume of liquefied methane is about 1/600 that of the gaseous methane in a standard state, The specific gravity is 0.42, which is about one half of that of crude oil.

LNG is liquefied with ease of transportation and used after vaporizing at the place of use after transportation. However, due to the risk of natural disasters and terrorism, it is feared to install LNG vaporization equipment onshore.

As a result, in place of the conventional liquefied natural gas regeneration system installed on the land, a facility for supplying natural gas that is vaporized on the ground by installing a regeneration device on an LNG carrier carrying a liquefied natural gas have.

A large amount of energy is required in the course of performing heat exchange to increase the temperature of the LNG on the LNG regasification apparatus. Therefore, in order to solve the problem that the energy used in this process is wasted due to inefficient exchange, a method of exchanging heat using seawater is used. However, there is a problem that the equipment or facilities used for LNG heat exchange are weakened in durability and life span due to salt, microorganisms, or suspended substances contained in seawater in such seawater-based heat exchange method.

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the conventional art as described above, and it is an object of the present invention to provide an apparatus and a system for heating LNG in which a fresh water pump and a fresh water tank are additionally provided, By flushing the used seawater lines and facilities with fresh water, it is possible to prevent corrosion and erosion by microorganisms, salt, etc., of various devices and facilities used for seawater, thereby increasing durability.

The object of the present invention is also to provide a chemical pump and a chemical tank additionally installed in an apparatus for constituting LNG heating and cleaning the system with chemical water to a seawater line and facilities used in an apparatus constituting LNG heating, Provided is an LNG processing system and method that can prevent corrosion and erosion by microorganisms, salt, etc., of various facilities used in seawater, and then flush remaining chemicals with fresh water, thereby increasing the durability to facilities and equipment .

An LNG treatment system according to an embodiment of the present invention includes a seawater line connecting a seawater pump and an LNG heat exchanger and discharging seawater to the outside; A seawater pump provided on the sea water line for supplying seawater to the LNG heat exchanger; An LNG heat exchanger provided on the sea water line for exchanging heat with seawater to the LNG; A chemical supply line connecting the chemical storage tank and the seawater pump or the seawater line; And a water supply line provided on the chemical supply line, connected between the chemical storage tank and the seawater pump, for supplying chemical when the heating of the LNG stops, and when the chemical cleaning process is stopped And a chemical pump that stops chemical supply.

Specifically, a fresh water supply line connecting the fresh water tank and the sea water pump or the sea water line; And a fresh water pump provided on the fresh water supply line and connected between the fresh water tank and the seawater pump and supplying clean water to the seawater pump or the seawater line.

A chemical return line connecting the LNG heat exchanger and the chemical storage tank; And a purifier disposed on the chemical return line and connected between the LNG heat exchanger and the chemical storage tank, the purifier cleaning the chemical; The LNG heat exchanger may further include a chemical measuring device disposed on the chemical return line and located between the LNG heat exchanger and the purifier to measure a chemical concentration of the fluid discharged from the LNG heat exchanger.

Specifically, it is preferable that the chemical pump has a function of controlling the chemical flow rate of the fluid flowing on the chemical return line so that the difference between the concentration of the chemical measured by the chemical measurement device and the chemical present in the chemical storage tank If it is mine, the chemical supply can be stopped.

The LNG heat exchanger may further include a salt measuring device disposed on the sea water line and measuring the salinity of the fluid discharged from the LNG heat exchanger, the salt measuring device being positioned downstream of the LNG heat exchanger.

Specifically, the LNG supply line may further include an LNG fuel supply line connecting the LNG heat exchanger and allowing the LNG to flow.

Specifically, the LNG heat exchanger exchanges heat between the LNG and the seawater, and the LNG absorbs heat from the seawater, and the seawater can release heat to the LNG.

Specifically, the clean water pump can supply clean water to the seawater pump or the seawater line when the cleaning process using chemicals is stopped.

Specifically, the fresh water pump can stop the supply of fresh water when the difference between the concentration of salt measured by the salinity measuring device and fresh water is within a predetermined value range for the fluid flowing on the sea water line.

Specifically, the chemical may be a substance that prevents corrosion or erosion of the sea water line.

Specifically, the purifier may receive the chemical containing the corrosive matter from the LNG heat exchanger, purify the chemical from the corrosive matter, and return the purified chemical to the chemical storage tank.

In addition, the LNG treatment method according to an embodiment of the present invention is a method for operating an LNG treatment system including a seawater pump for supplying seawater to an LNG heat exchanger, a purifier, a chemical tank, a chemical pump, Supplying seawater to the LNG heat exchanger using the seawater pump; Exchanging heat between seawater and LNG in the LNG heat exchanger; Discharging seawater to the outside in the LNG heat exchanger; Stopping the inflow of seawater into the seawater pump when the heating process of the LNG is stopped; Supplying the chemical from the chemical tank to the seawater pump or the seawater line using the chemical pump; Cleaning the seawater line using chemicals; And a chemical measuring device for measuring the concentration of the chemical substance in the chemical solution when the difference between the concentration of the chemical substance measured by the chemical measuring device and the chemical is within a predetermined value range for the fluid flowing on the seawater line, And stopping the supply.

Specifically, in the LNG heat exchanger, a chemical containing a corrosive substance is supplied to the purifier. Purifying the chemical containing the corrosive substance in the purifier; And supplying purified chemicals from the clarifier to the chemical storage tank.

Specifically, the LNG treatment system includes a fresh water supply line connecting the fresh water tank and the seawater pump; And a fresh water pump provided on the fresh water supply line and connected between the fresh water tank and the seawater pump and supplying clear water to the seawater pump.

Specifically, the LNG treatment system may further include a salt measuring device disposed on the sea water line, the salt measuring device being positioned at a downstream end of the LNG heat exchanger and measuring a concentration of salinity of the fluid discharged from the LNG heat exchanger.

Specifically, when the cleaning process using the chemical stops, stopping the chemical supply with the seawater pump; Supplying clean water from the fresh water tank to the seawater pump or the sea water line using the fresh water pump; Flushing the seawater line with fresh water; And stopping the supply of fresh water from the fresh water pump to the seawater pump or the seawater line when the difference of the concentration of the salt measured by the salinity measuring device with respect to fresh water is within a predetermined value range with respect to the fluid flowing on the seawater line The method comprising the steps of:

Specifically, the chemical may be a substance that prevents corrosion or erosion of the sea water line.

Specifically, when the cleaning process using the chemical stops, the step of stopping the chemical supply with the seawater pump is performed such that the concentration of the chemical measured by the chemical measuring device with respect to the fluid flowing on the chemical returning line If the difference from the chemical present in the chemical storage tank is within the predetermined value range, the cleaning process is stopped and the chemical supply can be stopped.

The LNG treatment system and method according to the present invention is characterized in that LNG heating is performed by flushing and cleaning the apparatus or equipment constituting the LNG heating by using the fresh water pump, fresh water tank, chemical water pump and chemical tank after LNG heating Corrosion and erosion of the apparatus or equipment constituting the structure of the present invention can be prevented, and durability can be increased to prolong the service life of the equipment, so that the operating efficiency can be improved.

1 is a conceptual diagram of a conventional LNG processing system.
2 is a conceptual diagram of an LNG processing system according to an embodiment of the present invention.
3 is a conceptual diagram of an LNG processing system according to another embodiment of the present invention.
4 is a flow chart of the LNG treatment method according to an embodiment of the present invention.
5 is a flowchart of a method of treating LNG according to another embodiment of the present invention.
6 is a partial flowchart of a method of treating LNG according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram of a conventional LNG processing system.

1, the conventional LNG processing system 1 includes a seawater pump 10, an LNG heat exchanger 20, a seawater line 21, and an LNG fuel supply line 22.

Hereinafter, the LNG may be used to encompass not only a liquid state NG but also a NG state such as a supercritical state for the sake of convenience. The evaporation gas may include not only gaseous state evaporation gas but also liquefied evaporation gas Can be used as a meaning.

  The conventional LNG processing system 1 uses seawater pump 10 to supply seawater to LNG heat exchanger 20 to exchange heat between LNG and seawater.

However, in this case, since seawater is used, corrosion or erosion of facilities or equipment occurs due to microorganisms or salt existing in seawater, resulting in deterioration of service life of the equipment and consequent deterioration of operating efficiency.

2 is a conceptual diagram of an LNG processing system according to an embodiment of the present invention.

2, the LNG processing system 2 according to an embodiment of the present invention includes a seawater pump 10, an LNG heat exchanger 20, a salinity measurement device 23, a fresh water tank 30, And a fresh water pump 40. The seawater pump 10 and the LNG heat exchanger 20, the seawater line 21 and the LNG fuel supply line 22 are the same as those of the conventional LNG processing system 1, Reference numerals are used to designate the same or similar components.

The seawater pump 10 is provided on the seawater line 21 and supplies the seawater to the LNG heat exchanger 20. The seawater pump 10 may be a centrifugal pump. The seawater pump 10 can receive fresh water from a fresh water pump 40 to be described later. Through this, the saline and microorganisms of the seawater remaining in the seawater pump 10 can be removed by fresh water, Can be protected, and the durability enhancement can prolong the life.

A seawater line 21 is connected to the seawater pump 10 and the seawater line 21 connects the seawater pump 10 and the LNG heat exchanger 20 to discharge seawater to the outside. A seawater valve (not shown) is installed in the seawater line 21, and the supply amount of the seawater can be adjusted according to the opening degree of the seawater valve.

The LNG heat exchanger (20) is provided on the sea water line (21) to exchange heat between the seawater and the LNG. The LNG heat exchanger 20 exchanges heat between the LNG and the seawater, the LNG absorbs heat from the seawater, and the seawater can release heat to the LNG. Seawater can be supplied to the LNG heat exchanger 20 by the seawater pump 10 and clean water is supplied to the seawater pump 10, the seawater line 21 or the LNG heat exchanger 20 when the LNG heating is stopped .

The seawater or fresh water heat-exchanged in the LNG heat exchanger 20 can be discharged outboard, and the LNG heat-exchanged in the LNG heat exchanger 20 can be supplied to an LNG consumer (not shown). An LNG fuel supply line 22 is connected to the LNG heat exchanger 20 so that the LNG can flow and the LNG fuel supply line 22 is provided with an LNG fuel supply valve The supply amount of LNG can be adjusted by controlling the opening degree of the LNG.

The salinity measuring device 23 is disposed on the seawater line 21 and is located at the rear end of the LNG heat exchanger 20 and can measure the salinity of the fluid discharged from the LNG heat exchanger 20. [ The salinity measuring device 23 measures the salinity of the fluid discharged from the LNG heat exchanger 20 and transmits the measured value to the clean water pump 40 by wire or wire.

The fresh water tank 30 stores fresh water to be supplied to the seawater pump 10 or the sea water line 21. The fresh water stored in the fresh water tank 30 can be supplied to the seawater pump 10 or the seawater line 21 by the fresh water pump 40 when the LNG heating process is stopped, Thereby to improve the durability and extend the service life of the apparatus or equipment in which the seawater flows by removing the remaining seawater.

The fresh water can be removed by passing the seawater line 21 or the apparatus or equipment through which the seawater flows such as the seawater pump 10 or the LNG heat exchanger 20 to remove seawater remaining in the facility, It is possible to prevent erosion and corrosion caused by other floats and the like.

The fresh water supply line 31 connects the fresh water tank 30 and the sea water pump 10 or the sea water line 21. A fresh water supply valve (not shown) is provided in the fresh water supply line 31 so that the supply amount of fresh water can be adjusted according to the opening degree adjustment of the fresh water supply valve.

The fresh water pump 40 is provided on the fresh water supply line 31 and is connected between the fresh water tank 30 and the seawater pump 10 and supplies fresh water to the seawater pump 10 or the seawater pump 10 when the LNG heating is stopped. (21). The fresh water pump 40 can stop the supply of fresh water when the difference of the concentration of the salt measured by the salt measurement device 23 with respect to the fluid flowing on the sea water line 21 is within the preset value range have.

The fresh water pump 40 can receive the value of the concentration of the salt measured by the salinity measurement device 23 from the salinity measurement device 23 by wired or wireless. Further, the fresh water pump 40 calculates the difference from the concentration of the salt contained in the fresh water based on the information on the concentration of the received salt, and when the difference value is within the predetermined value range, for example, If it is ~ 10%, the supply of fresh water can be stopped. Since the residual seawater in the device or equipment in which the seawater flows is removed by the flushing process of the fresh water, the difference between the salinity of the saline measurement device (23) and the concentration of the salt contained in the fresh water is 1 to 10% Only the fresh water is present in the device or equipment, so the supply of fresh water may be interrupted.

As described above, in the present embodiment, the fresh water pump 40 and the fresh water tank 30 are additionally provided in the apparatus or the equipment constituting the LNG heating, and the seawater line 21 used in the apparatus and the equipment constituting the LNG heating, And flushing the facility with fresh water, it is possible to prevent corrosion and erosion by microorganisms, salt, and the like of various apparatuses and facilities used in the apparatus or the equipment constituting the LNG heating, thereby increasing the durability. In addition, it is possible to induce efficient flushing by installing the salinity measuring device 23, and waste of fresh water can be prevented.

3 is a conceptual diagram of an LNG processing system according to another embodiment of the present invention.

3, the LNG processing system 3 according to another embodiment of the present invention includes a seawater pump 10, an LNG heat exchanger 20, a seawater line 21, an LNG fuel supply line 22, A salinity measuring device 23, a chemical measuring device 24, a fresh water tank 30, a fresh water supply line 31, a fresh water pump 40, a chemical storage tank 50, a chemical pump 60, A chemical supply line 51, a chemical return line 52, and a purifier 70. [

In another embodiment of the present invention, the chemical measurement device 24, the fresh water pump 40, the chemical storage tank 50, the chemical pump 60, the chemical supply line 51, the chemical return line 52 And the purifier 70 are similar to those described above in the LNG processing system 2 according to the embodiment, detailed description will be omitted.

The chemical measuring device 24 is provided on the chemical return line 21 and is located between the LNG heat exchanger 20 and the purifier 70 and measures the concentration of the chemical discharged from the LNG heat exchanger 20 . That is, the chemical measuring device 24 measures the concentration of a specific chemical, and is not limited to any particular chemical, which is a chemical capable of preventing corrosion and erosion or removing corrosive matter from a specific chemical.

The chemical measuring device 24 measures the concentration of the chemical discharged from the LNG heat exchanger 20 and transmits the measured value to the chemical pump 60 by wire or wire.

The fresh water pump 40 can supply clean water to the seawater pump 10 when the cleaning process using chemicals is stopped and the fresh water can be supplied to the seawater line 21 by the saline measurement device 23 The supply of fresh water can be stopped when the concentration of salt and the difference are within the preset range.

The fresh water pump 40 can receive the value of the concentration of the salt measured by the salinity measurement device 23 from the salinity measurement device 23 by wired or wireless. Further, the fresh water pump 40 calculates the difference from the concentration of the salt contained in the fresh water based on the information on the concentration of the received salt, and when the difference value is within the predetermined value range, for example, If it is ~ 10%, the supply of fresh water can be stopped. Since the residual seawater in the device or equipment in which the seawater flows is removed by the flushing process of the fresh water, the difference between the salinity of the saline measurement device (23) and the concentration of the salt contained in the fresh water is 1 to 10% Only the fresh water is present in the device or equipment, so the supply of fresh water may be interrupted.

Unlike the embodiment of the present invention, fresh water is not supplied to the seawater pump 10 or the seawater line 21 even if the LNG heating is stopped, and the cleaning process of the chemical takes place first. Protection and prevention of corrosion and erosion of facilities and equipment that use seawater as a primary chemical cleaning process, and facilities and devices that use seawater as a secondary process of flushing fresh water when the chemical cleaning process is stopped Thereby removing the remaining chemicals and seawater. The sequential process as described above prevents erosion or corrosion by seawater, increases durability, and can prolong the life of the equipment.

The chemical storage tank 50 may store chemicals to be supplied to the seawater line 21 or the seawater pump 10. The chemical stored in the chemical storage tank 50 can be supplied to the seawater pump 10 or the seawater line 21 by the chemical pump 60 when the LNG heating process is stopped, By carrying out the cleaning work, it is possible to prevent, protect and remove corrosion or erosion of equipment or equipment by remaining seawater, thereby improving the durability and extending the service life of the equipment or equipment.

The chemical may be a substance that prevents the corrosion of the sea water line 21, and may be a substance that decomposes or removes the corrosive substance when the corrosion progresses. Such chemical is passed through the apparatus and equipment in which the seawater flows such as the seawater line 21 or the seawater pump 10 or the LNG heat exchanger 20 to remove the seawater remaining in the facility, To prevent erosion and corrosion caused by microorganisms or other floating matters.

The chemical supply line 51 connects the chemical storage tank 50 and the seawater pump 10 or the seawater line 21. A chemical supply valve (not shown) is provided in the chemical supply line 51 so that the supply amount of the chemical can be adjusted according to the opening degree of the chemical supply valve.

The chemical water pump 60 is provided on the chemical supply line 51 and is connected between the chemical storage tank 50 and the seawater pump 10 and supplies the chemical when the heating of the LNG is stopped And stops the chemical supply when the cleaning process using the chemical stops. The chemical pump 60 may be a centrifugal pump.

The chemical water pump 60 can receive the value of the concentration of the chemical measured by the chemical measuring device 24 from the chemical measuring device 24 by wire or wireless. Further, the chemical pump 60 calculates the difference between the concentration of the chemical contained in the fluid discharged from the LNG heat exchanger 20 and the difference between the concentration of the chemical contained in the fluid discharged from the LNG heat exchanger 20, , For example, if the preset value range is about 1 to 10%, the chemical supply can be stopped. The difference between the concentration of the chemical contained in the fluid discharged from the chemical measuring device 24 and the LNG heat exchanger 20 is 1 (%) because the remaining corrosive matter or by- To 10%, whereby the supply of chemicals may be interrupted due to the presence of chemicals only in the apparatus or equipment in which the seawater flows.

The purifier 70 is provided on the chemical return line 52 and is connected between the LNG heat exchanger 20 and the chemical storage tank 50 to purify the chemical. Also, the purifier 70 can receive the chemical containing the corrosive matter from the LNG heat exchanger 20, purify the chemical from the corrosive matter, and return the purified chemical to the chemical storage tank 50.

In the case where LNG heating is stopped, the purifier 70 starts to purify the chemical containing the corrosive material. When the cleaning operation of the chemical is stopped, the purifier 70 performs the purifying process on the supplied chemical material. You can stop. In addition, the purifier 70 is supplied with a fluid containing a corrosive substance, floating substance or seawater, which is in the state of a mixture or in a state of a compound, and is supplied with the original chemical and the remaining corrosive matter, Seawater, etc. can be separated and cleaned to obtain pure chemicals.

The chemical return line 52 may connect the LNG heat exchanger 20 and the chemical storage tank 50. A chemical return valve (not shown) is provided on the chemical return line 52, and the supply amount of the chemical can be adjusted according to the adjustment of the opening of the chemical return valve.

As described above, in the present embodiment, the chemical water pump 60 and the chemical storage tank 50 are additionally provided in the apparatus or the equipment for constituting the LNG heating, and the seawater line 21) and the facilities are cleaned with chemicals, corrosion and erosion of various facilities used for LNG heating are prevented by microorganisms, salt, etc., and after that the remaining water is flushed with clean water, Can be increased. In addition, the salinity measurement device 23 or the chemical measurement device 24 can be installed to efficiently flush the wastewater, thereby preventing the wastewater from being wasted.

However, unlike the embodiment of the present invention, the fresh water is not supplied to the seawater pump 10 or the seawater line 21 even if the LNG heating is stopped, and the cleaning process of the chemical takes place first. Protection and prevention of corrosion and erosion of facilities and equipment that use seawater as a primary chemical cleaning process, and facilities and devices that use seawater as a secondary process of flushing fresh water when the chemical cleaning process is stopped Thereby removing the remaining chemicals and seawater. The sequential process as described above prevents erosion or corrosion by seawater, increases durability, and can prolong the life of the equipment.

4 is a flow chart of the LNG treatment method according to an embodiment of the present invention. The LNG processing method according to an embodiment of the present invention can be implemented by the LNG processing system in the embodiment described above, and each step of the LNG processing method will be described below.

4, the LNG processing method according to one embodiment of the present invention includes a method of operating an LNG processing system including a seawater pump for supplying seawater to the LNG heat exchanger, a seawater line, a fresh water tank, and a fresh water pump (S10) of supplying seawater to the LNG heat exchanger by using a seawater pump, exchanging seawater and LNG in an LNG heat exchanger (S20), discharging seawater from the LNG heat exchanger to the outside (S30) (S40), stopping the inflow of seawater into the seawater pump when the heating process of the seawater pump is stopped, supplying the fresh water from the fresh water tank to the seawater pump or the seawater line using the fresh water pump (S50) A step S60 of stopping the supply of fresh water supplied from the fresh water pump to the seawater pump when the difference between fresh water and fresh water is within a predetermined value range, 0).

The LNG processing system for driving each stage may further include a salinity measuring device provided on the sea water line and positioned at the rear end of the LNG heat exchanger.

In step S10, seawater is supplied to the LNG heat exchanger using a seawater pump. The seawater pump 10 can supply seawater to the LNG heat exchanger 20 through the seawater line 21 so that the LNG and the seawater can be heat-exchanged.

In step S20, the LNG heat exchanger performs heat exchange between the seawater and the LNG. The LNG heat exchanger 20 exchanges heat between the LNG and the seawater. The LNG absorbs heat from the seawater, and the seawater can release heat to the LNG. The LNG heat exchanger 20 receives the LNG from the LNG storage tank (not shown) and exchanges heat between the LNG and the seawater, and the heat exchanged LNG can be supplied to the LNG consumer (not shown).

In step S30, the LNG heat exchanger releases seawater to the outside. The LNG heat exchanger 20 receives seawater from the seawater pump 10 and exchanges heat with the LNG, and the seawater that is heat-exchanged is discharged to the outside, so that it can be discharged outboard.

In step S40, when the heating process of the LNG is stopped, the inflow of seawater to the seawater pump is stopped. When the heating process of the LNG is stopped or the heat exchange is stopped in the LNG heat exchanger 20, the supply of the LNG to be heat-exchanged with the seawater is stopped, so that the inflow of seawater by the seawater pump can be stopped.

In step S50, the fresh water is supplied from the fresh water tank to the sea water pump or the sea water line by using the fresh water pump. When the LNG heating process is stopped, the fresh water can be supplied to the seawater pump or the seawater line by using the fresh water pump at the same time or after the stop of the inflow of the seawater by the seawater pump.

In step S60, the sea water line is flushed with fresh water. The fresh water passes through the seawater line 21 or the apparatus and equipment in which the seawater flows such as the seawater pump 10 or the LNG heat exchanger 20 to thereby remove the seawater remaining in the facility, It is possible to prevent erosion and corrosion caused by other floats and the like. As the flushing operation proceeds, the remaining seawater can be removed to improve the durability and extend the service life of the seawater facility or the apparatus.

In step S70, when the difference of the salt concentration measured by the salinity measuring device with fresh water is within the predetermined value range, the fresh water pump stops the supply of fresh water supplied to the sea water pump. The fresh water pump 40 can receive the value of the concentration of the salt measured by the salinity measuring device 23 from the salinity measuring device 23 by wire or wire. Based on the received information, the concentration of the salt contained in the fresh water And the supply of fresh water can be stopped when the difference value is within the predetermined value range, for example, about 1 to 10% in the preset value range. In other words, the concentration of the salt of the fluid flowing through the facility or the apparatus using the seawater becomes very small and has the same or very small difference as the fresh water, so that the removal of the remaining seawater is completed, Supply can be stopped.

As described above, the LNG treatment method according to the present embodiment is characterized in that a fresh water pump and a fresh water tank are additionally provided in an apparatus or a facility for LNG heating, so that fresh water It is possible to prevent corrosion and erosion due to microorganisms, salt, and the like in various apparatuses and facilities used in the apparatus or the equipment constituting the LNG heating, thereby increasing the durability.

5 is a flowchart of a method of treating LNG according to another embodiment of the present invention. The LNG processing method according to another embodiment of the present invention can be implemented by the LNG processing system in the embodiment described above, and each step of the LNG processing method will be described below.

5, the LNG processing method according to another embodiment of the present invention includes a method of driving an LNG processing system including a seawater pump for supplying seawater to the LNG heat exchanger, a seawater line, a fresh water tank, and a fresh water pump (S10) of supplying seawater to the LNG heat exchanger by using a seawater pump, exchanging seawater and LNG in an LNG heat exchanger (S20), discharging seawater from the LNG heat exchanger to the outside (S30) (S40) of stopping the inflow of the seawater to the seawater pump when the heating process of the chemical water is stopped (S40), supplying the chemical from the chemical storage tank to the seawater pump or the seawater line using the chemical pump (S50) (S60), and when the difference between the concentration of the chemical measured by the chemical measuring device and the chemical is within a predetermined value range with respect to the fluid flowing on the sea water line, Stopping the supply of the chemical to the seawater pump or the seawater line from the chemical pump (S70); stopping the chemical supply with the seawater pump (S110) if the cleaning process using the chemical stops; (S130) of supplying the fresh water to the seawater pump or the sea water line (S120), flushing the sea water line using the fresh water (S130), and measuring the concentration of the salt measured by the measuring device And stopping the supply of fresh water to the seawater pump when the difference between the first set value and the second set value is within the preset value range (S140).

A step of supplying seawater to the LNG heat exchanger using a seawater pump, a step of exchanging seawater and LNG in an LNG heat exchanger (S20), a step of discharging seawater from the LNG heat exchanger to the outside (S30) Step S40 of stopping the inflow of seawater into the seawater pump when the process is stopped is the same as or similar to the step described in the LNG processing method according to the first embodiment, and thus a detailed description thereof will be omitted.

In step S50, a chemical pump is used to supply the chemical from the chemical storage tank to the seawater pump or seawater line. When the LNG heating process is stopped, the chemical water is supplied to the seawater pump 10 or the seawater line 21 by using the chemical pump 60 at the same time or after the stop of the inflow of the seawater to the seawater pump 10 . In this embodiment, unlike in the embodiment, chemical can be supplied to the seawater pump 10 or the sea water line 21 in order to perform cleaning before flushing.

In step S60, the seawater line is cleaned using chemicals. The chemical stored in the chemical storage tank 50 can be supplied to the seawater pump 10 or the seawater line 21 by the chemical pump 60 when the LNG heating process is stopped, By carrying out the cleaning work, it is possible to prevent, protect and remove corrosion or erosion of equipment or equipment by residual seawater, thereby improving the durability and extending the service life of the equipment or equipment.

The chemical may be a substance that prevents the corrosion of the sea water line 21, and may be a substance that decomposes or removes the corrosive substance when the corrosion progresses. Such chemical is passed through the apparatus and equipment in which the seawater flows such as the seawater line 21 or the seawater pump 10 or the LNG heat exchanger 20 to remove the seawater remaining in the facility, To prevent erosion and corrosion caused by microorganisms or other floating matters.

In step S70, when the difference between the concentration of the chemical measured by the chemical measuring device and the chemical is within a predetermined value range for the fluid flowing on the seawater line, the chemical pump changes from the chemical pump to the seawater pump or the sea water line Stop the supply of chemicals. The chemical water pump 60 can receive the value of the concentration of the chemical measured by the chemical measuring device 24 from the chemical measuring device 24 in a wired or wireless manner. Based on the received information, And if the difference value is within the preset value range, for example, the preset value range is about 1 to 10%, the chemical supply can be stopped. In other words, the concentration of the chemical of the fluid flowing in the facility or apparatus using the seawater becomes so large that it has the same or very small difference as the chemical, so that the removal of the residual corrosive matter or byproducts is completed, The supply of chemicals can be discontinued.

In step S110, when the chemical cleaning process is stopped, the chemical supply is stopped by the seawater pump. When the cleaning process is stopped, the chemical supply is stopped by the seawater pump 10 in order to carry out the flushing process to cleanly remove the mixture of the chemical and the seawater remaining in the sea water line 21.

If the measured concentration of the chemical measuring device 24 is within the preset range, it is determined that the cleaning process is stopped, and the supply of the chemical is stopped, and the predetermined range is, for example, about 1 to 10% .

In step S120, fresh water is supplied to the seawater pump or the sea water line by using the fresh water pump. When the cleaning operation using chemicals is stopped, the seawater pump 10 or the seawater pump 10 is operated by using the fresh water pump 40 in order to perform the flushing process to clean the seawater containing the chemicals remaining in the seawater line 21 Fresh water can be supplied to the sea water line 21.

In step S130, the sea water line is flushed with fresh water. The fresh water passes through the seawater line 21 or the apparatus and equipment in which the seawater flows such as the seawater pump 10 or the LNG heat exchanger 20 to thereby remove the seawater remaining in the facility, It is possible to prevent erosion and corrosion caused by other floats and the like. As the flushing operation proceeds, the remaining seawater can be removed to improve the durability and extend the service life of the seawater facility or the apparatus.

In step S140, when the difference of the concentration of the salt measured by the measuring device with respect to fresh water is within a predetermined value range, the supply of fresh water is stopped by the seawater pump. The fresh water pump 40 can receive the value of the concentration of the salt measured by the salinity measuring device 23 from the salinity measuring device 23 by wire or wire. Based on the received information, the concentration of the salt contained in the fresh water And the supply of fresh water can be stopped when the difference value is within the predetermined value range, for example, about 1 to 10% in the preset value range. In other words, the concentration of the salt of the fluid flowing through the facility or the apparatus using the seawater becomes very small and has the same or very small difference as the fresh water, so that the removal of the remaining seawater is completed, Supply can be stopped.

6 is a partial flowchart of a method of treating LNG according to another embodiment of the present invention. The LNG processing method according to another embodiment of the present invention can be implemented by the LNG processing system in the embodiment described above, and each step of the LNG processing method will be described below.

As shown in FIG. 6, the LNG treatment method according to another embodiment of the present invention includes the steps of supplying a chemical containing a corrosive substance to a purifier in an LNG heat exchanger (S80) (S90), and supplying the purified chemical in the purifier to the chemical storage tank (S100).

6 begins with the process of step S60 of FIG. 5, and the end of FIG. 6 proceeds to step S50 of FIG. 5 and continues. However, even if the process of cleaning the seawater line 21 using chemicals is stopped, the present loop may continue, and when the process of the LNG processing method according to another embodiment of the present invention shown in FIG. 5 is terminated, .

In step S80, the LNG heat exchanger supplies the chemical containing the corrosive substance to the purifier. When the seawater line 21 is cleaned using chemicals, byproducts generated by the chemical reaction between the chemicals and the corrosive substances on the seawater line 21 are generated. In order to purify the by-products and return them to the present chemical, To provide cleaned chemical containing chemicals.

In step S90, the chemical containing the corrosive substance is purified in the purifier. When the LNG heating is stopped, the chemical containing the corrosive matter is supplied to start to purify. If the cleaning operation of the chemical is stopped, the purified chemical can be finally stopped and the purified chemical can be stopped. However, the present invention is not limited to this, and the purifier can purify chemicals mixed with fresh water even during the flushing operation.

In addition, the purifier 70 is supplied with a fluid containing a corrosive substance, floating substance or seawater, which is in the state of a mixture or in a state of a compound, and is supplied with the original chemical and the remaining corrosive matter, Seawater, etc. can be separated and cleaned to obtain pure chemicals.

In step S100, the purified water is supplied to the chemical storage tank by the purifier. The chemicals purified in the clarifier 70 can be returned to the chemical storage tank 50 and the purified and remaining byproducts can be recovered using a variety of separation devices such as a filter (not shown) or a desalination facility (not shown) The suspended solids can be filtered using a filter to store them in a waste storage facility (not shown), and the remaining fluid can be used to produce fresh water using a desalination facility so that the produced fresh water can be stored in an extra storage facility have.

As described above, the LNG processing method according to the present embodiment is characterized in that a chemical water pump 60 and a chemical storage tank 50 are additionally provided in an apparatus or a facility for constituting the LNG heating, By cleaning the used seawater line 21 and the facility with chemicals, it is possible to prevent corrosion and erosion of microbes, salts, and the like of various facilities used for LNG heating, and then, Thereby increasing the durability of equipment and equipment. In addition, the salinity measurement device 23 or the chemical measurement device 24 can be installed to efficiently flush the wastewater, thereby preventing the wastewater from being wasted.

However, unlike the embodiment of the present invention, the fresh water is not supplied to the seawater pump 10 or the seawater line 21 even if the LNG heating is stopped, and the cleaning process of the chemical takes place first. Protection and prevention of corrosion and erosion of facilities and equipment that use seawater as a primary chemical cleaning process, and facilities and devices that use seawater as a secondary process of flushing fresh water when the chemical cleaning process is stopped Thereby removing the remaining chemicals and seawater. The sequential process as described above prevents erosion or corrosion by seawater, increases durability, and can prolong the life of the equipment.

1: conventional LNG processing system 2, 3: LNG processing system of the present invention
10: Seawater pump 20: LNG heat exchanger
21: sea water line 22: LNG fuel supply line
23: Salt measuring device 24: Chemical measuring device
30: fresh water tank 31: fresh water supply line
40: fresh water pump 50: chemical storage tank
51: chemical supply line 52: chemical return line
60: chemical pump 70: purifier

Claims (18)

A seawater line connecting seawater pump and LNG heat exchanger and discharging seawater to the outside;
A seawater pump provided on the sea water line for supplying seawater to the LNG heat exchanger;
An LNG heat exchanger provided on the sea water line for exchanging heat with seawater to the LNG;
A fresh water supply line connecting the fresh water tank and the seawater pump or the seawater line;
A fresh water pump provided on the fresh water supply line and connected between the fresh water tank and the seawater pump for supplying clean water to the seawater pump or the seawater line;
A chemical supply line connecting the chemical storage tank and the seawater pump or the seawater line;
A chemical supply line connected to the chemical storage tank and the seawater pump for supplying chemical when the heating of the LNG stops and a chemical A chemical pump that stops water supply; And
And a salt measuring device disposed on the seawater line for measuring the salinity of the fluid discharged from the LNG heat exchanger, the salt measuring device being located at a downstream end of the heat exchanger. delete The method according to claim 1,
A chemical return line connecting the LNG heat exchanger and the chemical storage tank; And
A purifier disposed on the chemical return line and connected between the LNG heat exchanger and the chemical storage tank for purifying the chemical;
Further comprising a chemical measuring device disposed on the chemical return line and located between the LNG heat exchanger and the purifier for measuring the chemical concentration of the fluid discharged from the LNG heat exchanger, . 4. The chemical pump according to claim 3,
And stopping the supply of the chemical when the difference between the concentration of the chemical measured by the chemical measuring device and the chemical present in the chemical storage tank for the fluid flowing on the chemical return line is within a predetermined value range Characterized by an LNG processing system. delete The method according to claim 1,
Further comprising an LNG fuel supply line connecting the LNG heat exchanger and allowing the LNG to flow. 2. The LNG heat exchanger according to claim 1,
Exchanges heat between LNG and seawater, LNG absorbs heat from seawater, and seawater releases heat to LNG. 2. The water treatment system according to claim 1,
And the fresh water is supplied to the seawater pump or the seawater line when the cleaning process using chemicals is stopped. 2. The water treatment system according to claim 1,
Wherein the supply of fresh water is stopped when the difference between the salt concentration measured by the salinity measuring device and fresh water is within a predetermined value range for the fluid flowing on the sea water line. The method of claim 1,
Wherein the material is a material that prevents corrosion or erosion of the seawater line. The apparatus according to claim 3,
Wherein the LNG heat exchanger is supplied with a chemical containing a corrosive substance, and the chemical is purified from the corrosive substance, and the purified chemical is returned to the chemical storage tank. A method for operating an LNG processing system including a seawater pump, a purifier, a chemical tank and a chemical pump, and a chemical meter for supplying seawater to an LNG heat exchanger,
Supplying seawater to the LNG heat exchanger using the seawater pump;
Exchanging heat between seawater and LNG in the LNG heat exchanger;
Discharging seawater to the outside in the LNG heat exchanger;
Stopping the inflow of seawater into the seawater pump when the heating process of the LNG is stopped;
Supplying chemical from the chemical tank to the seawater pump or seawater line using the chemical pump;
Cleaning the seawater line using chemicals; And
When the difference between the concentration of the chemical measured by the chemical measuring device and the chemical is within a predetermined value range for the fluid flowing on the seawater line, the chemical pump supplies the chemical to the seawater pump or the seawater line And,
Wherein the LNG treatment system further comprises a salinity measuring device provided on the seawater line and positioned at a downstream end of the LNG heat exchanger for measuring a concentration of salinity of a fluid discharged from the LNG heat exchanger, . 13. The method of claim 12,
Supplying chemical containing a corrosive substance to the purifier in the LNG heat exchanger;
Purifying the chemical containing the corrosive substance in the purifier; And
And supplying the purified chemical in the purifier to the chemical tank. 13. The LNG treatment system according to claim 12,
A fresh water supply line connecting the fresh water tank and the seawater pump; And
Further comprising a fresh water pump provided on the fresh water supply line and connected between the fresh water tank and the seawater pump to supply clean water to the seawater pump. delete 15. The method of claim 14,
Stopping the chemical supply with the seawater pump when the chemical cleaning process is stopped;
Supplying clean water from the fresh water tank to the seawater pump or the sea water line using the fresh water pump;
Flushing the seawater line with fresh water; And
When the difference of the concentration of salt measured by the salinity measuring device with respect to fresh water is within a predetermined value range for the fluid flowing on the sea water line, the fresh water pump stops the supply of fresh water to the sea water pump or the sea water line Further comprising the step of: 17. The method of claim 16,
Wherein the material is a material that prevents corrosion or erosion of the seawater line. 17. The method of claim 16, wherein stopping the chemical supply with the seawater pump when the chemical cleaning process is stopped comprises:
It is determined that the cleaning process is stopped when the difference between the concentration of the chemical measured by the chemical measuring device and the chemical present in the chemical storage tank is within the predetermined value range for the fluid flowing on the chemical return line Thereby stopping the supply of the chemical.

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