WO2013058308A1

WO2013058308A1 - Pressure rise suppression device for storage tank, pressure rise suppression system provided therewith, suppression method therefor, liquefied gas carrying vessel provided therewith, and liquefied gas storage facility provided therewith

Info

Publication number: WO2013058308A1
Application number: PCT/JP2012/076921
Authority: WO
Inventors: 岡　勝
Original assignee: 三菱重工業株式会社
Priority date: 2011-10-20
Filing date: 2012-10-18
Publication date: 2013-04-25
Also published as: CN103857955A; KR101688705B1; EP2775194A4; JP2013087911A; EP2775194A1; CN103857955B; EP2775194B1; KR20140051459A

Abstract

In order to suppress pressure rise in a storage tank for storing liquefied gas, simplify a facility and lower the cost of the facility, a pressure rise suppression device for a storage tank is provided with: the storage tank (2) in which liquefied gas is stored; a heat exchange means (4) in which the liquefied gas in a liquid state extracted from the storage tank (2) and a refrigerant exchange heat with each other; a refrigerant compression means (31) which compresses the refrigerant led to the heat exchange means (4); a refrigerant expansion means (33) which reduces the pressure of the refrigerant compressed by the refrigerant compression means (31) and supplies the refrigerant to the heat exchange means (4), and a supply means (11) which supplies the liquefied gas in the liquid state cooled in the heat exchange means (4) to the liquefied gas in the liquid state in the storage tank (2).

Description

Pressure rise suppressing device for storage tank, pressure rise suppressing system having the same, method for suppressing the same, liquefied gas carrier having the same, and liquefied gas storage facility having the same

The present invention relates to a pressure rise suppression device for a storage tank, a pressure rise suppression system including the same, a method of suppressing the same, a liquefied gas carrier equipped with the same, and a liquefied gas storage facility equipped with the same. The present invention relates to suppression of pressure rise in a storage tank.

Generally, in a storage tank (hereinafter referred to as "cargo tank") in which liquefied gas such as liquefied natural gas (hereinafter referred to as "LNG") or liquefied petroleum gas (hereinafter referred to as "LPG") is stored in liquid form. , Reliquefy the vaporized gas to suppress an increase in the internal pressure of the cargo tank due to liquefied gas (hereinafter referred to as "boil-off gas") that is naturally vaporized by the external heat input to the cargo tank, re-liquefy gas from the cargo tank Are extracted and burned and disposed of externally.

As a boil-off gas reliquefaction device, for example, as shown in FIG. 7, in the reliquefaction device 101 of the liquefied petroleum gas carrier transporting LPG, the boil off gas in the cargo tank 102 is compressed to a high pressure by the boil off gas compressor 103. Then, the compressed boil-off gas is heat-exchanged with seawater (design temperature: about 32 ° C.) drawn outboard in the condenser 104, cooled, and condensed at about 40 ° C. The LPG thus condensed is partially gasified when it is introduced to the cargo tank 102 and decompressed (expanded) in the cargo tank 102. At this time, the temperature of the liquid LPG stored in the cargo tank 102 is lowered using the cold heat from which the LPG evaporates, and the total amount (total amount of gas phase) of the boil-off gas in the cargo tank 102 is reduced. Suppress the pressure in 102.

FIG. 8 shows a process diagram when, for example, propane is reliquefied using the reliquefaction apparatus 101 shown in FIG. The vertical axis in FIG. 8 represents pressure (MPa), and the horizontal axis represents specific enthalpy (kJ / kg).

I in FIG. 8 indicates that the liquid LPG stored in the cargo tank 102 shown in FIG. 7 evaporates into boil-off gas, and II indicates compression of the boil-off gas by the boil-off gas compressor 103 , III show the cooling of the boil-off gas by seawater in the condenser 104, IV shows that the condensed LPG expands in the cargo tank 102 to gas-cool the liquid LPG stored in the cargo tank 102. There is.

In the reliquefaction apparatus 101 shown in FIG. 7, for example, a reciprocating multi-stage boil-off gas compressor 103 having a piston 107 in a cylinder 105 and a drive unit 111 for driving the piston 107 via a crankshaft 109 is used. Boil-off gas is compressed to a high pressure of about 16 atm to 20 atm and supplied to the condenser 104. Further, as the condenser 104, a seawater cooling type plate or shell-and-tube type heat exchanger is used.

Further, the reliquefaction apparatus provided in the liquefied natural gas carrier for transporting LNG is a supercritical fluid where methane, which is the main component of LNG, is near normal temperature, and the seawater temperature region led to the condenser 104 shown in FIG. At about 32 ° C., the boil-off gas of LNG can not be liquefied. Therefore, the LPG reliquefaction device 101 can not be used directly as the LNG reliquefaction device.

Therefore, as shown in FIG. 9, as the LNG reliquefaction apparatus 201, an indirect cooling method by Brayton cycle using nitrogen as a refrigerant is adopted. That is, in the reliquefaction apparatus 201, the boil-off gas generated in the cargo tank 202 passes through the boil-off gas supply pipe 209, is pressurized by the boil-off gas compressor 203 through the boil-off gas thermal relaxation and separator 207, and indirectly It is led to a cooling type cold box 204. Thereafter, the boil-off gas exchanges heat with nitrogen gas as a refrigerant in the indirect cooling type cold box 204. By exchanging heat with nitrogen gas in the cold box 204, the boil-off gas is condensed and subcooled and becomes liquid. The liquid condensed (reliquefied) LNG passes through the reliquefaction gas pipe 205 and is introduced into the cargo tank 202 again. The pressure increase in the cargo tank 202 is suppressed by reliquefying the boil off gas in this manner.
The boil-off gas thermal relaxation / separator 207 is connected to a reliquefaction LNG supply pipe 211 for extracting and supplying a part of the LNG reliquefied in the cold box 204. In the boil-off gas thermal relaxation / separator 207, the boil-off gas is cooled (thermal relaxation) by the reliquefied LNG supplied from the reliquefaction LNG supply pipe 211, and the gas and liquid are separated.

FIG. 10 shows a process diagram of the case where LNG is reliquefied using the reliquefaction apparatus 201 shown in FIG. 9, the vertical axis shows pressure (MPa) and the horizontal axis shows specific enthalpy. (KJ / kg) is shown.
10 is also the same as FIG. 8, and I in FIG. 10 shows that LNG is evaporated in the cargo tank 202 shown in FIG. 9 to become boil-off gas, and II is boil-off gas by the boil-off gas compressor 203 , And III indicate the cooling of the boil-off gas by nitrogen in the cold box 204, and IV indicates that the pressure in the cargo tank 202 is reduced.

Nitrogen is used as the refrigerant led to the cold box 204 of the reliquefaction apparatus 201 shown in FIG. The nitrogen is compressed to a high pressure over three stages of a two-stage nitrogen compressor 231 and a nitrogen booster 232. That is, nitrogen pressurized to a high pressure by the nitrogen compressor 231 is led to the cold box 204 and heat-exchanged with the low pressure and low temperature nitrogen gas obtained by cooling and condensing the boil-off gas to lower the temperature. The temperature-reduced high-pressure nitrogen is led to a nitrogen expander 233 coaxially provided with the nitrogen booster 232. The high pressure nitrogen led to the nitrogen expander 233 is decompressed to be a low temperature low pressure nitrogen gas. The low temperature and low pressure nitrogen gas is led to the cold box 204 again, and is subjected to heat exchange in order of the boil off gas and the above-mentioned high pressure nitrogen and is led out of the cold box 204. The nitrogen derived from the cold box 204 is led to the nitrogen booster 232, compressed by the nitrogen booster 232 and led to the inlet of the nitrogen compressor 231.
The nitrogen compressed by the nitrogen compressor 231 is cooled by the first heat exchanger 235 before entering the cold box 204, and the heat of compression is removed. In addition, a second heat exchanger 237 is also provided between the nitrogen booster 232 and the nitrogen compressor 231 so that the compression heat of nitrogen boosted by the nitrogen booster 232 is removed. .

JP, 2009-58199, A

In ships carrying both LPG and LNG, it has been considered necessary to carry both the LPG reliquefaction unit 101 shown in FIG. 7 and the LNG reliquefaction unit 201 shown in FIG. . However, when both these

systems

101 and 201 are mounted on one ship, there existed a problem of causing complication of installation and the increase in installation cost.

Further, according to Patent Document 1, the laser processing machine is cooled by cooling the coolant stored in the coolant tank with the heat exchanger by means of a heat exchanger, and returning the coolant to the coolant tank. Although it is disclosed to cool, this is the temperature control of the coolant for cooling the laser processing machine, and it is not disclosed about the method of suppressing the pressure rise in the cargo tank storing the liquefied gas. .

The present invention has been made in view of such circumstances, and it is possible to suppress a pressure rise in a storage tank storing liquefied gas, and simplify the facility and reduce the cost of the facility. An object of the present invention is to provide a pressure rise suppression device, this pressure rise suppression system, this suppression method, a liquefied gas carrier equipped with the same, and a liquefied gas storage facility equipped with the same.

In the storage tank pressure rise suppression device according to the first aspect of the present invention, there is provided a storage tank storing a liquefied gas, and a heat exchange in which the liquefied gas in a liquid state extracted from the storage tank exchanges heat with the refrigerant. A refrigerant compression unit for compressing the refrigerant introduced to the heat exchange unit; an refrigerant expansion unit for decompressing the refrigerant compressed by the refrigerant compression unit and supplying the refrigerant to the heat exchange unit; And supply means for supplying the liquid liquefied gas cooled by the heat exchange means to the liquid liquefied gas in the storage tank.

The liquid liquefied gas extracted from the storage tank is cooled by heat exchange with the refrigerant in the heat exchange means, and the cooled liquid liquefied gas is returned to the liquid liquefied gas in the storage tank by the supply means. Thus, the liquid liquefied gas stored in the storage tank can be cooled by the liquid liquefied gas supplied from the supply means. Therefore, it is possible to suppress the gasification of the liquid liquefied gas by reducing the temperature of the entire liquid liquefied gas in the storage tank. At this time, since only the liquid phase (single phase) of the liquefied gas to be circulated is subjected to heat exchange in the heat exchange means, in the heat exchange means, the pressure difference corresponding to the temperature difference given by the refrigerant by the heat exchange means is As long as it is provided, the temperature of the liquid liquefied gas introduced to the storage tank can be set to a temperature corresponding to the storage tank. Therefore, the liquid liquefied gas stored in the storage tank can be cooled to suppress the pressure increase in the storage tank.

Further, when heat exchange between the liquid liquefied gas and the refrigerant is performed in the heat exchange means, the temperature difference of the liquefied gas at the inlet / outlet of the heat exchange means is small because it is carried out only in the liquid phase state without phase change of the liquefied gas. It becomes smaller. Therefore, the temperature difference of the refrigerant at the inlet and outlet of the heat exchange means also decreases. Since the temperature difference of the refrigerant is proportional to the pressure difference of the refrigerant, as a result, the pressure difference of the refrigerant at the inlet and outlet of the heat exchange means is reduced. As a result, the compression ratio of the refrigerant compression means for compressing the refrigerant introduced to the heat exchange means can be reduced, and the number of stages of the refrigerant compression means can be reduced. In addition, since the number of stages of the refrigerant compression means is reduced, the design of the refrigerant compression means is facilitated, and mechanical loss of the refrigerant compression means can be reduced. Furthermore, since the cooling is performed without accompanying the phase change of the liquid liquefied gas led to the heat exchange means, the heat exchange efficiency of the heat exchange means can be enhanced. Therefore, the heat exchange means can be made compact. Therefore, the pressure rise suppression device can be simplified and the efficiency of the entire device can be improved.

In addition, as liquefied gas, liquefied natural gas (LNG), liquefied petroleum gas (LPG), ethane, ethylene, ammonia, those mixtures, etc. are mentioned.

In the storage tank pressure rise suppression device according to the second aspect of the present invention, a storage tank storing a liquefied gas, and heat generated by heat exchange between the refrigerant and the liquefied gas in a liquid state extracted from the storage tank. Exchange means, refrigerant compression means for compressing the refrigerant introduced to the heat exchange means, refrigerant expansion means for decompressing the refrigerant compressed by the refrigerant compression means, and supplying the pressure to the heat exchange means; And a spraying unit configured to spray the liquid liquefied gas cooled by the heat exchange unit to the gaseous liquefied gas in the storage tank.

The liquid liquefied gas extracted from the storage tank is cooled by heat exchange with the refrigerant in the heat exchange means, and the cooled liquid liquefied gas is dispersed to the gaseous liquefied gas in the storage tank by the dispersing means. The gaseous liquefied gas can be condensed (reliquefied) by heat exchange between the liquefied gas thus cooled and the gaseous liquefied gas in the storage tank. That is, the supercooling heat of the cooled liquid liquefied gas increases the particle size of the cooled liquid liquefied gas dispersed in the gaseous liquefied gas. Thereafter, the liquefied gas having the increased particle size falls on the surface (liquid surface) of the liquefied gas stored in the storage tank. Therefore, the pressure rise in the storage tank by gaseous liquefied gas can be suppressed, or the pressure in the storage tank can be reduced.

In the storage tank pressure rise suppression device according to the third aspect of the present invention, a storage tank storing a liquefied gas, and a heat exchange in which the liquefied gas in a liquid state extracted from the storage tank and the refrigerant exchange heat. A refrigerant compression unit for compressing the refrigerant introduced to the heat exchange unit; an refrigerant expansion unit for decompressing the refrigerant compressed by the refrigerant compression unit and supplying the refrigerant to the heat exchange unit; The supply means for supplying the liquid liquefied gas cooled by the heat exchange means to the liquid liquefied gas in the storage tank, and the liquid liquefied gas cooled by the heat exchange means in the storage tank And sparging means for sparging the gaseous liquefied gas.

The liquid liquefied gas extracted from the storage tank is cooled by heat exchange with the refrigerant in the heat exchange means, and the cooled liquid liquefied gas is supplied by the supply means to the liquid liquefied gas in the storage tank, and by the dispersing means It was decided to disperse to liquefied gas in the upper gas layer in the storage tank. As a result, the temperature of the entire liquid liquefied gas in the storage tank is lowered to suppress gasification of the liquid liquefied gas, and the liquid gas in the upper part of the storage tank is recondensed (reliquefyed) be able to. Therefore, suppression and pressure reduction of the pressure rise in a storage tank can be performed.

Further, in the pressure rise suppression device for a storage tank according to the present invention, the supply means may include a supply flow rate adjustment means for adjusting the supply flow rate of the liquid liquefied gas cooled by the heat exchange means. .

By providing the supply flow rate adjusting means for adjusting the flow rate supplied to the liquid liquefied gas in the storage tank of the liquid liquefied gas cooled by the heat exchange means, the liquid that is cooled by the heat exchange means The liquefied gas can be supplied to the storage tank at a flow rate equivalent to the amount of heat input to the storage tank from the outside. Therefore, even when the temperature of the whole liquid liquefied gas in the storage tank rises due to the heat input, the pressure rise in the storage tank can be suppressed.

Further, in the pressure rise suppression device for a storage tank according to the present invention, the spreading means may include a spreading amount adjusting means for adjusting a spreading amount of the liquefied gas cooled by the heat exchange means. .

By providing a spraying amount adjustment means for regulating the amount of spraying of liquid liquefied gas cooled by the heat exchange means into the gaseous liquefied gas in the storage tank, the gaseous form in the storage tank is provided. The flow rate of the cooled liquid liquefied gas sprayed to the liquefied gas can be adjusted to adjust the rate at which the gaseous liquefied gas in the storage tank condenses (reliquefaction). Therefore, the pressure in the storage tank by the gaseous liquefied gas can be adjusted to make the inside of the storage tank equal to or less than a predetermined pressure.

In the storage tank pressure rise suppression device according to the present invention, a part of the liquid liquefied gas led to the heat exchange means is bypassed from the heat exchange means and led to the supply means and / or the dispersion means. The fuel cell system may further include bypass means and bypass flow rate adjusting means for adjusting a bypass flow rate through which the liquefied gas passes through the bypass means.

A bypass means is provided for bypassing part of the liquid liquefied gas extracted from the storage tank from the heat exchange means to the supply means and / or the dispersing means, and the bypass means includes liquid liquefied gas passing through the bypass means. By providing a bypass flow rate adjusting means for adjusting the flow rate of the liquid, mixing the liquid liquefied gas cooled by the heat exchange means and the liquid liquefied gas not cooled by the heat exchange means, the supply means and / or It is possible to adjust the temperature of the liquid liquefied gas to be introduced to the spraying means. Therefore, the pressure rise in the storage tank can be suppressed by adjusting the ratio of the cooling of the liquid liquefied gas stored in the storage tank and / or the condensation (reliquefaction) of the gaseous liquefied gas.

Further, in the pressure rise suppression device for a storage tank according to the present invention, the storage tank is provided between a storage tank, the storage tank, and the heat exchange means, and the liquid extracted from the storage tank is A liquefied gas and / or an intermediate vessel in which the gaseous liquefied gas is temporarily stored; the supply means and / or the dispersing means are provided in the intermediate vessel; The liquid liquefied gas cooled by the heat exchange means may be led.

By providing the storage tank and the intermediate tank and returning the liquid liquefied gas cooled by the heat exchange means to the intermediate tank, the heat exchange means can be used even if the capacity of the storage tank is relatively small. A part of the liquid liquefied gas cooled by the heat exchange means can be stored in the intermediate tank without introducing the whole amount of the cooled liquid liquefied gas into the storage tank. Therefore, even when the capacity of the storage tank is relatively small, the liquid liquefied gas in the storage tank can be cooled to an appropriate temperature.

Further, by providing the intermediate tank with the supplying means and the dispersing means, the dispersing means and the supplying means can be maintained without making the storage tank gas-free. Therefore, maintenance of the pressure rise suppression device is facilitated.

In the pressure rise suppression system according to the fourth aspect of the present invention, the storage tank is provided in a plurality, and the liquefied gas stored in each storage tank is a gas type different for each storage tank. The pressure rise suppression apparatus of the storage tank which concerns on b.

By using the pressure rise suppression device that performs heat exchange in the heat exchange means only for the liquid phase (single phase) of the liquefied gas to be circulated, the pressure difference corresponding to the temperature difference that the refrigerant gives in the heat exchange means As long as it is provided, a wide variety of liquefied gases stored in each storage tank can be cooled by one pressure rise suppressor. Therefore, the pressure rise suppression system can be simplified and the equipment cost can be reduced.

A liquefied gas carrier according to a fifth aspect of the present invention includes the pressure rise suppression system according to the fourth aspect of the present invention.

According to the liquefied gas carrier according to the fifth aspect of the present invention, since the natural gas processing facility using the compact reliquefaction plant is mounted, the installation space required for these can be reduced.
Therefore, the pressure rise suppression system mounted on the liquefied gas carrier can be simplified and the equipment cost can be reduced.

A liquefied gas storage facility according to a sixth aspect of the present invention includes the pressure rise suppression system according to the fourth aspect of the present invention.

It was decided to use a pressure rise suppression system capable of cooling a wide variety of liquefied gases stored in each storage tank by using the pressure rise suppression device 1 described above. Therefore, the pressure rise suppression system mounted on the liquefied gas carrier can be simplified and the equipment cost can be reduced.

In the storage tank pressure increase suppressing method according to the seventh aspect of the present invention, the liquid liquefied gas extracted from the storage tank storing the liquefied gas and the refrigerant decompressed after being compressed are heated The liquid gas is exchanged to cool the liquid gas, and the liquid gas is cooled by heat exchange to the liquid gas stored in the storage tank and / or the liquefied gas in a gaseous state. Lead.

Only the liquid phase (single phase) of the liquefied gas to be circulated is cooled by heat exchange with the refrigerant, and the cooled liquid liquefied gas is led to the liquid and / or gaseous liquefied gas in the storage tank. . Thereby, the temperature of the entire liquid liquefied gas in the storage tank is lowered to suppress gasification of the liquid liquefied gas in the storage tank, or the gaseous liquefied gas in the storage tank is condensed to It can be liquefied. Therefore, suppression and pressure reduction of the pressure rise of a storage tank can be performed.

According to the present invention, the liquid liquefied gas extracted from the storage tank is cooled by heat exchange with the refrigerant in the heat exchange means, and the cooled liquid liquefied gas is supplied to the liquid liquefied gas in the storage tank by the supply means. I decided. Thus, the liquid liquefied gas stored in the storage tank can be cooled by the liquid liquefied gas supplied from the supply means. Therefore, it is possible to suppress the gasification of the liquid liquefied gas by reducing the temperature of the entire liquid liquefied gas in the storage tank. At this time, since only the liquid phase (single phase) of the liquefied gas to be circulated is subjected to heat exchange in the heat exchange means, in the heat exchange means, the pressure difference corresponding to the temperature difference given by the refrigerant by the heat exchange means is As long as it is provided, the temperature of the liquid liquefied gas introduced to the storage tank can be set to a temperature corresponding to the storage tank. Therefore, the liquid liquefied gas stored in the storage tank can be cooled to suppress the pressure increase in the storage tank.

Further, when heat exchange between the liquid liquefied gas and the refrigerant is performed in the heat exchange means, the temperature difference of the liquefied gas at the inlet / outlet of the heat exchange means is small because it is carried out only in the liquid phase state without phase change of the liquefied gas It becomes smaller. Therefore, the temperature difference of the refrigerant at the inlet and outlet of the heat exchange means also decreases. Since the temperature difference of the refrigerant is proportional to the pressure difference of the refrigerant, as a result, the pressure difference of the refrigerant at the inlet and outlet of the heat exchange means is reduced. As a result, the compression ratio of the refrigerant compression means for compressing the refrigerant introduced to the heat exchange means can be reduced, and the number of stages of the refrigerant compression means can be reduced. Further, by reducing the number of stages of the refrigerant compression means, the design of the refrigerant compression means is facilitated, and mechanical loss of the refrigerant compression means can be reduced. Furthermore, since the cooling is performed without accompanying the phase change of the liquid liquefied gas led to the heat exchange means, the heat exchange efficiency of the heat exchange means can be enhanced. Therefore, the heat exchange means can be made compact. Therefore, the pressure rise suppression device can be simplified and the efficiency of the entire device can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic block diagram of the pressure rise suppression apparatus of the storage tank mounted in the liquefied natural gas carrier concerning 1st Embodiment of this invention. It is the process conceptual diagram of the pressure by the pressure rise suppression apparatus shown in FIG. 1, and specific enthalpy. It is a graph which shows the relationship of the temperature of the liquefied natural gas and heat exchange amount in a cold box, (A) shows the conventional case, and (B) shows the case of this embodiment. It is a conceptual diagram which shows each temperature difference in the inlet-outlet of the cold box shown in FIG. 1 of nitrogen and recirculation LNG, and the pressure ratio of nitrogen in the inlet-outlet of a nitrogen compressor. 5 is a graph showing the relationship between the temperature of nitrogen shown in FIG. 4 and the temperature difference and pressure ratio of nitrogen at the cold box inlet / outlet. It is a schematic block diagram of the pressure rise suppression apparatus of the storage tank mounted in the liquefied natural gas carrier according to a second embodiment of the present invention. It is a schematic block diagram which shows the reliquefaction apparatus mounted in the conventional liquefied petroleum gas carrier. It is a process figure of propane at the time of using the reliquefaction device shown in FIG. It is a schematic block diagram which shows the reliquefaction apparatus mounted in the conventional liquefied natural gas carrier. It is a process figure of methane (liquefied natural gas) at the time of using the reliquefaction device shown in FIG.

First Embodiment A liquefied natural gas carrier equipped with a pressure rise suppression system for a storage tank according to a first embodiment of the present invention will be described based on FIGS. 1 and 2.
FIG. 1 is a schematic configuration view of a pressure rise suppression device of a cargo tank constituting a pressure rise suppression system mounted on a liquefied natural gas carrier according to the present embodiment, and FIG. 2 is shown in FIG. The process conceptual diagram of the pressure and the specific enthalpy by a pressure rise suppression device is shown, the vertical axis shows pressure (MPa) and the horizontal axis shows specific enthalpy (kJ / kg).

In a liquefied natural gas carrier (liquefied gas carrier) (not shown), as shown in FIG. 1, a cargo tank (storage tank) 2 storing liquefied natural gas (liquefied gas) and a liquid extracted from the cargo tank 2 Cold box (heat exchange means) in which the liquefied natural gas (hereinafter referred to as “recycled LNG”) and nitrogen (refrigerant) exchange heat, and a nitrogen compressor (refrigerant) which compresses the nitrogen led to the cold box 4 For compression means 31), a nitrogen booster (compression means for refrigerant) 32, a nitrogen expander for decompressing the nitrogen compressed by the nitrogen compressor 31 and the nitrogen booster 32 and supplying it to the cold box 4 (expansion for refrigerant Means 33) The liquid recirculated LNG cooled in the cold box 4 is supplied to the liquid liquefied natural gas (hereinafter referred to as "LNG") stored in the cargo tank 2. Boil off for spraying piping (supply means) 11 and liquid recirculating LNG cooled in cold box 4 to boil off gas (gaseous LNG) stored in upper space (not shown) in cargo tank 2 A pressure rise suppression device 1 having a gas distribution nozzle (dispersion means) 18 is mounted.

In the liquefied natural gas carrier equipped with the pressure rise suppression device 1 having such a configuration, a plurality of cargo tanks 2 storing LNG as cargo (only one tank is shown in FIG. 1). A plurality of cargo tanks 2 and the pressure rise suppression device 1 are combined to constitute a pressure rise suppression system.

The pressure rise suppression device 1 cools a portion of liquid LNG, which is cargo stored in the cargo tank 2, and boil-off gas stored in the upper space in the cargo tank 2 and in the cargo tank 2. An LNG recycling system 10 for recirculating to liquid LNG stored in the lower part, and a nitrogen refrigeration cycle 30 for circulating nitrogen which is in heat exchange with the recycled LNG which is liquid LNG extracted from the inside of the cargo tank 2 have.

The LNG recirculation system 10 exchanges the heat between the LNG circulating pump 12 for extracting a part of the liquid LNG stored in the cargo tank 2 and the recirculated LNG extracted by the LNG circulating pump 12 and nitrogen. A cold box 4 in which liquid recirculating LNG is cooled, a pipe 11 for leading the recirculating LNG cooled in the cold box 4 to the vicinity of the bottom of the cargo tank 2, and a part of the recirculating LNG led to the cold box 4 A bypass pipe (bypassing means) 13 for bypassing from the cold box 4 and joining the pipe 11 and a pipe 11 on the downstream side of the joining point where the bypass pipe 13 joins the pipe 11 are branched from A pipe 14 for guiding a portion of the cooled liquid recirculated LNG into the space, and an end portion of the pipe 14 are stored in the upper space in the cargo tank 2. And a boil-off gas spray nozzle 18 for spraying the recirculated LNG liquid cooled to BOG being.

Furthermore, a bypass flow control valve (bypass flow rate adjusting means) 15 is provided on the bypass piping 13 of the LNG recirculation system 10 to adjust the bypass flow rate of the recirculation LNG led to the bypass piping 13. The spray control valve (dispersion amount adjustment means) 16 for adjusting the amount of dispersed liquid recirculated LNG cooled in the cold box 4 and the junction downstream of the pipe 14 on the pipe 11 And a recirculation control valve (supply flow rate adjusting means) 17 for adjusting the amount of recirculation (supply flow rate) of the liquid recirculation LNG cooled in the cold box 4.

In addition, the temperature at which the temperature of liquid recirculating LNG passing through the inside of the pipe 11 is measured on the pipe 11 between the junction of the pipe 11 and the bypass pipe 13 and the junction of the pipe 11 and the pipe 14 Measuring means 19 are provided.

The cargo tank 2 stores liquid LNG, which is a cargo. Such a cargo tank 2 has a heat insulation structure, but the heat input from the outside to the cargo tank 2 heats the liquid LNG stored in the cargo tank 2 and a part of it is evaporated. The evaporated LNG is stored in the upper space above the liquid level of the liquid LNG stored in the cargo tank 2 as the boil-off gas.

The cargo tank 2 is provided with a cargo handling pump, which is used when cargo liquid LNG is stored in the stored liquid LNG. In the case of the present embodiment, the cargo handling pump is combined with the LNG circulation pump 12 used to circulate the recirculated LNG in the LNG recirculation system 10, but the present invention is not limited to this.

Further, in the cargo tank 2, in addition to the piping 11 and the piping 14, a vent piping 21 capable of extracting the boil-off gas stored in the upper space in the cargo tank 2 from the inside of the cargo tank 2 to the outside Connected to the top of 2.

The cold box 4 is an indirect cooling type heat exchanger that cools the liquid recirculated LNG by heat exchange between the nitrogen led from the nitrogen refrigerant cycle 30 and the liquid recirculated LNG led from the LNG recirculation system 10 It is. The cold box 4 includes a precooling unit C1 and a cooling unit C2. In the precooling unit C1, heat exchange is performed between low-pressure low-temperature nitrogen gas introduced from the nitrogen refrigerant cycle 30, which will be described later, and high-pressure nitrogen compressed by the nitrogen compressor 31. In addition, in the cooling unit C2, heat exchange is performed between the low temperature and low pressure nitrogen gas and the liquid recirculation LNG led from the LNG recirculation system 10.

The nitrogen refrigerant cycle 30 supplies nitrogen, which is a refrigerant, to the cold box 4. The nitrogen refrigerant cycle 30 is a nitrogen brought to a high pressure by the cold box 4 in which the liquid recirculated LNG and the nitrogen led to heat exchange between the LNG recirculation system 10 described above, the nitrogen compressor 31 and the nitrogen booster 32. A nitrogen expander 33 for reducing pressure, a first heat exchanger 34 for cooling high pressure nitrogen compressed by the nitrogen compressor 31, and a second heat exchanger 35 for cooling nitrogen compressed by the nitrogen booster 32. have.

The nitrogen compressor 31 is a single-stage compressor, which sucks and compresses nitrogen as a refrigerant to obtain high-temperature, high-pressure nitrogen.
The nitrogen booster 32 compresses the liquid recycle LNG led from the LNG recycle system 10 in the cold box 4 and the heat-exchanged nitrogen. Further, the nitrogen booster 32 has a rotating shaft 36, and a nitrogen expander 33 is provided coaxially with the rotating shaft 36.

The nitrogen expander 33 is for expanding high pressure nitrogen whose temperature has been lowered from the nitrogen compressor 31 through the cold box 4 into low temperature low pressure nitrogen gas by reducing pressure. The rotational shaft 36 is driven with the force when the compressed nitrogen expands as a rotational force, and the nitrogen booster 32 is rotationally driven.

The first heat exchanger 34 cools the nitrogen, which has been brought into high pressure by the nitrogen compressor 31, with fresh water or the like as a refrigerant to lower the temperature.
The second heat exchanger 35 cools the nitrogen compressed by the nitrogen booster 32 with fresh water as a refrigerant to lower the temperature.
In addition, as a refrigerant | coolant of the 1st heat exchanger 34 and the 2nd heat exchanger 35, seawater may be sufficient.

Next, the suppression method of the pressure rise suppression device 1 according to the present embodiment will be described using FIGS. 1 and 2.
Here, FIG. 2 shows a process conceptual diagram of the pressure and the specific enthalpy by the pressure rise suppression device 1 shown in FIG. 1.

In the LNG recirculation system 10 shown in FIG. 1, liquid LNG stored in the cargo tank 2 is discharged to the pipe 20 by the LNG circulation pump 12. (I in FIG. 2). The liquid recycle LNG led to the pipe 20 is led from the pipe 20 to the cold box 4 (II in FIG. 2). The liquid recirculating LNG led to the cold box 4 is cooled by heat exchange with the low temperature low pressure nitrogen gas led from the piping 37 of the nitrogen refrigerant cycle 30 to the cold box 4 in the cooling part C2 of the cold box 4 Be done. (III in FIG. 2).

Here, in the case of the present embodiment, when liquid recirculating LNG exchanges heat with nitrogen gas in the cooling portion C2 of the cold box 4, it is provided in the conventional LNG reliquefaction apparatus 201 shown in FIG. Unlike the case where gaseous LNG, ie, boil-off gas, is condensed and subcooled in the cold box 204, the liquid recirculated LNG is cooled as it is in single phase without undergoing a condensation process.

A bypass pipe 13 for bypassing the cold box 4 is connected to the pipe 20, and a bypass flow control valve 15 is provided on the bypass pipe 13. Therefore, when the bypass flow control valve 15 is opened, a part of the liquid recirculating LNG led from the pipe 20 to the cold box 4 passes through the bypass pipe 13.

The liquid recirculating LNG cooled in the cold box 4 and the liquid recirculating LNG not cooled by passing through the bypass pipe 13 are merged and mixed in the pipe 11. The mixed liquid recirculated LNG is introduced into the cargo tank 2 by the pipe 11, is introduced near the bottom in the cargo tank 2 through the nozzle 18-2, and is stored in the cargo tank 2. Lower the temperature of the entire liquid LNG. (IV in FIG. 2).

Here, the cargo tank 2 is adjusted by adjusting the degree of opening of the bypass flow control valve 15 based on the temperature of the liquid recirculating LNG passing through the inside of the pipe 11 measured by the temperature measuring means 19 provided in the pipe 11. It is possible to adjust the temperature of the liquid recycle LNG circulated inside.

In addition, recirculation LNG, which is a mixture of the liquid recirculation LNG cooled in the cold box 4 and the liquid recirculation LNG not cooled (passed through the bypass piping 13), is transferred from the piping 11 to the piping 14 A part branches off and is sprayed from the boil-off gas distribution nozzle 18 to the boil-off gas stored in the upper space in the cargo tank 2. (V in FIG. 2).

By heat exchange between the atomized supercooled liquid recirculated LNG (droplets) and the boil off gas in the tank, the boil off gas is condensed by the supercooling heat of the droplets. The condensed and reliquefied boil-off gas drops onto the liquid phase surface of the liquid LNG stored in the cargo tank 2 (VI in FIG. 2). Thus, the pressure in the cargo tank 2 due to the boil-off gas is reduced by reliquefying the boil-off gas stored in the cargo tank 2. Therefore, the pressure rise in the cargo tank 2 can be prevented, and the pressure can be reduced.

A recirculation control valve 17 and a spray control valve 16 are provided on the pipe 11 and the pipe 14 in the vicinity of the outside of the cargo tank 2. By adjusting the opening degree of the recirculation control valve 17 and the spray control valve 16, liquid LNG stored in the cargo tank 2 and recirculated supercooled liquid supplied to the boil-off gas, respectively. The flow rate of LNG can be adjusted.

In the nitrogen refrigerant cycle 30, the nitrogen compressor 31 is driven by a drive source (not shown) to compress nitrogen introduced through the pipe 38 to a high temperature and a high pressure. The compressed nitrogen at high temperature is introduced from the nitrogen compressor 31 through the pipe 39 to the first heat exchanger 34. The high temperature and high pressure nitrogen led to the first heat exchanger 34 exchanges heat with fresh water which is a refrigerant. The high pressure nitrogen, which is heat exchanged with fresh water and cooled, is led out from the first heat exchanger 34 to the pipe 40. The temperature-reduced high-pressure nitrogen led to the pipe 40 is introduced into the cold box 4.

The high pressure nitrogen introduced from the piping 40 to the cold box 4 is heat exchanged with the nitrogen gas supplied from the piping 37 described later into the cold box 4 in the precooling section C1 provided in the cold box 4 Cool. The high pressure nitrogen cooled in the precooling unit C1 is led from the precooling unit C1 to the nitrogen expander 33 via the pipe 41.

The high-pressure nitrogen introduced into the nitrogen expander 33 is expanded by reduced pressure to be a low-temperature low-pressure nitrogen gas. The low-temperature low-pressure nitrogen gas exchanges heat with the liquid recirculation LNG led from the piping 20 of the LNG recirculation system 10 into the cold box 4 through the piping 37 in the cooling unit C2 in the cold box 4 . The low temperature and low pressure nitrogen gas introduced from the pipe 37 to the cooling unit C2 applies the cold heat to the liquid recirculation LNG to cool the liquid recirculation LNG. The nitrogen gas heat-exchanged with the liquid recirculating LNG in the cooling section C2 is further led to the precooling section C1 in the cold box 4 to cool the high pressure nitrogen led from the pipe 40 described above.

The nitrogen gas heat-exchanged with high-pressure nitrogen introduced from the piping 40 in the precooling unit C1 is led to the piping 42 via the piping 41 and the nitrogen expander 33 and is led to the nitrogen booster 32. In the nitrogen booster 32, the nitrogen introduced from the pipe 42 is compressed. The compressed and high temperature nitrogen is led to a pipe 43 connected between the nitrogen booster 32 and the second heat exchanger 35. The compressed and high temperature nitrogen introduced to the pipe 43 is introduced into the second heat exchanger 35, and is cooled by heat exchange with fresh water as a refrigerant. The cooled nitrogen is led from the second heat exchanger 35 to the nitrogen compressor 31 through the pipe 38.
As described above, the nitrogen refrigerant cycle 30 is repeated.

The vent pipe 21 connected to the upper part of the cargo tank 2 is led to the outside through the cold box 4. The boil gas led from the vent pipe 21 to the cold box 4 exchanges heat with the nitrogen gas led from the pipe 37 of the nitrogen refrigerant cycle 30 in the order of the cooling portion C2 and the precooling portion C1 in the cold box 4. Thus, the boil-off gas is cooled by heat exchange with the nitrogen gas of the nitrogen refrigerant cycle 30. The cooled boil-off gas is derived from the cold box 4 and is led to a boiler (not shown) or the like for use as fuel gas or the like.

Here, the heat exchange of the boil-off gas in the cold box 204 of the conventional LNG reliquefaction apparatus 201 (see FIG. 9) and the heat exchange of liquid recirculated LNG in the cold box 4 of the pressure rise suppression device 1 of this embodiment. Compare with. FIG. 3 graphically shows the state of these heat exchanges, and FIG. 3 (A) shows the heat exchange of the boil-off gas in the cold box 204 of the conventional reliquefaction apparatus 201 shown in FIG. FIG. 3 (B) shows the heat exchange of the liquid recirculated LNG in the cold box 4 provided in the pressure rise suppression device 1 of the present embodiment. In FIG. 3A and FIG. 3B, the vertical axis indicates the temperature T of the boil-off gas, the liquid recirculation LNG, or the refrigerant, and the horizontal axis indicates the heat exchange amount.

Further, FIG. 4 is a conceptual diagram showing the temperature difference between nitrogen and liquid recirculating LNG at the inlet and outlet of the cold box 4 of the present embodiment and the pressure ratio of nitrogen at the inlet and outlet of the nitrogen compressor 31. .

Further, FIG. 5 shows a graph showing the relationship between the temperature of nitrogen, the temperature difference at the cold box inlet / outlet and the pressure ratio shown in FIG. 4, and the left vertical axis in FIG. The temperature at the outlet of the cold box 4 of nitrogen gas is shown, the horizontal axis shows the pressure ratio of nitrogen at the inlet and outlet of the cold box 4, and the right vertical axis shows the temperature difference at the inlet and outlet of the cold box. Further, the broken line L1 in FIG. 5 indicates the saturation temperature of nitrogen gas, the line L2 indicates the temperature of nitrogen gas at the outlet of the cold box 4, and the line L3 indicates the temperature difference of nitrogen gas at the inlet and outlet of the cold box 4. Is shown.

In the case of the conventional reliquefaction apparatus 201, as shown in FIG. 3A, the boil-off gas led to the cold box 204 is cooled in the cold box 204 by low temperature / low pressure nitrogen gas as a refrigerant. At this time, the LNG led to the inlet of the cold box 204 is in a gaseous state as shown by gas I in FIG. 3A and is cooled by nitrogen gas (II in FIG. 3A). The liquid and gaseous two-phase gas (III in FIG. 3 (A)). The LNG that has become the gas-liquid two phase is further condensed by heat exchange with nitrogen gas in the cold box 204, and is condensed and reliquefied (liquid state) (IV in FIG. 3A).

As described above, in the conventional reliquefaction apparatus 201, the boil-off gas is cooled (I in FIG. 3A) and then condensed (IV in FIG. 3A) to become liquid, so the inlet / outlet of the cold box 204 The temperature difference between the boil-off gas and the nitrogen at the point (b) in FIG. Therefore, in order to increase the temperature difference of nitrogen at the inlet and outlet of the cold box 204, it is necessary to increase the differential pressure at the inlet and outlet of the condenser 204, which is a refrigerant.

However, in the case of the present embodiment, the liquid recirculated LNG is led to the cold box 4. Therefore, as shown in FIG. 3 (B), only heat exchange between single phase (liquid) recirculating LNG (I in FIG. 3 (B)) and nitrogen gas (II in FIG. 3 (B) occurs. It becomes. Therefore, the temperature difference between the liquid recirculation LNG and nitrogen at the inlet / outlet of the cold box 4 is smaller than that in the conventional case of FIG. 3 (A) (V in FIG. 3 (B)).

As shown in I of FIG. 4 and FIG. 5, the temperature difference of nitrogen at the inlet and outlet of the cold box 4 is proportional to the pressure ratio of nitrogen at the inlet and outlet of the cold box 4. That is, the temperature difference of nitrogen at the inlet / outlet of the cold box 4 is proportional to the differential pressure (pressure ratio) at the inlet / outlet of the nitrogen compressor 31, as shown in II in FIG. 4 and in FIG. Therefore, if the temperature difference of nitrogen is reduced, the differential pressure generated by the nitrogen compressor 31 can also be reduced. Therefore, the required suction / discharge pressure ratio of the nitrogen compressor 31 provided in the nitrogen refrigerant cycle 30 is reduced, and the single-stage nitrogen compressor 31 is compared with the conventional two-stage nitrogen compressor 231 (see FIG. 9). The number of stages can be reduced.

Furthermore, in the case of the present embodiment, since a single phase of liquid recirculated LNG is cooled by heat exchange with nitrogen gas in the cold box 4, the cold box is compared to the conventional cold box 104 (see FIG. 9). The heat exchange rate of 4 can be improved to make the cold box 4 compact.

As mentioned above, according to the pressure rise suppression device 1 of the cargo tank 2 concerning this embodiment, the pressure rise suppression system provided with this, this suppression method, according to the liquefied natural gas carrier equipped with this, the following effects Play.
The liquid LNG (liquefied gas, recycled LNG) extracted from the cargo tank (storage tank) 2 is cooled by heat exchange with nitrogen gas (refrigerant) in a cold box (heat exchange means) 4, and the cooled liquid It was decided to supply recirculated LNG to the liquid LNG stored in the cargo tank 2 by means of piping (supply means) 11. Thereby, the liquid LNG stored in the cargo tank 2 can be cooled by the liquid recirculation LNG supplied from the pipe 11. Therefore, the temperature of the whole liquid LNG stored in the cargo tank 2 can be reduced, and the gasification of the liquid LNG can be suppressed. Under the present circumstances, in order to heat-exchange only the liquid phase (single phase) of recirculation LNG in the cold box 4, in the cold box 4, the pressure difference equivalent to the temperature difference which gaseous nitrogen gives in the cold box 4 is a nitrogen compressor ( The temperature of the liquid recirculating LNG led to the cargo tank 2 can be made to be the temperature corresponding to the cargo tank 2 because it is sufficient if it is provided by the refrigerant compression means 31) and the nitrogen booster (compressor compression means) 32. Therefore, the liquid LNG stored in the cargo tank 2 can be cooled to suppress the pressure rise of the cargo tank 2.

In addition, when heat exchange between the liquid recirculating LNG and the nitrogen gas is performed in the cold box 4, it is performed only in the liquid phase state without a phase change of the recycled LNG. The temperature difference of liquefied LNG becomes small. Therefore, the temperature difference of nitrogen at the inlet / outlet of the cold box 4 also decreases. Since the temperature difference of nitrogen is proportional to the pressure difference of nitrogen, as a result, the pressure difference of nitrogen at the inlet / outlet of the cold box 4 is reduced. As a result, the compression ratio of the nitrogen compressor 31 for compressing nitrogen introduced to the cold box 4 can be reduced to make the single-stage nitrogen compressor 31 (the number of stages of the nitrogen compressor 31 can be reduced ). In addition, the single-stage nitrogen compressor 31 facilitates the design of the nitrogen compressor 31 and can reduce mechanical loss of the nitrogen compressor 31. Furthermore, since the liquid recycled LNG led to the cold box 4 is cooled without a phase change, the heat exchange efficiency of the cold box 4 can be enhanced. Therefore, the cold box 4 can be made compact. Therefore, simplification of the pressure rise suppression device 1 and the efficiency of the pressure rise suppression device 1 as a whole can be improved.

The liquid recirculating LNG extracted from the cargo tank 2 is cooled by heat exchange with nitrogen gas in the cold box 4, and the cooled liquid recirculating LNG is cooled by the boil-off gas dispersion nozzle (dispersion means) 18 in the cargo tank 2. It was decided to spray to boil off gas (gaseous LNG). By heat exchange between the liquid recirculated LNG thus cooled and the boil-off gas in the cargo tank 2, the boil-off gas can be condensed (reliquefied). That is, the subcooling heat of the cooled liquid recycle LNG increases the particle size of the cooled liquid recycle LNG dispersed in the boil off gas. Thereafter, the liquid recirculated LNG having the increased particle size drops onto the surface (liquid surface) of the liquid LNG stored in the cargo tank 2. Therefore, the pressure rise in the cargo tank 2 due to the boil-off gas can be suppressed and the pressure in the cargo tank 2 can be reduced.

Recirculation to adjust the recirculation amount (flow rate) of liquid recirculating LNG that is liquid recirculating LNG cooled in the cold box 4 and led to the liquid LNG stored in the cargo tank 2 The control valve (supply flow rate adjusting means) 17 is provided in the supply means. As a result, it is possible to supply liquid recirculated LNG cooled by the cold box 4 to the cargo tank 2 at a flow rate equivalent to the amount of heat input to the cargo tank 2 from the outside. Therefore, even when the temperature of the whole liquid LNG stored in the cargo tank 2 rises due to the heat input, the pressure rise in the cargo tank 2 can be suppressed.

A spray control valve (dispersion amount adjusting means) 16 for adjusting the amount of the liquid recirculation LNG that is liquid cooled in the cold box 4 and is led to the boil-off gas in the cargo tank 2; It was decided to provide the boil-off gas distribution nozzle 18. Thereby, the flow rate of the cooled liquid recirculated LNG dispersed to the boil-off gas in the cargo tank 2 is adjusted to adjust the ratio of condensing (reliquefying) the boil-off gas in the cargo tank 2 it can. Therefore, the pressure in the cargo tank 2 due to the boil-off gas can be adjusted to make the inside of the cargo tank 2 equal to or less than the predetermined pressure.

A bypass piping (bypass means) 13 is provided which bypasses part of the liquid recirculating LNG extracted from the cargo tank 2 from the cold box 4 to the piping 11 and / or the boil-off gas dispersion nozzle 18. I decided. Further, the bypass pipe 13 is provided with a bypass flow control valve (bypass flow rate adjusting means) 15 for adjusting the bypass flow rate (flow rate) of liquid recirculating LNG passing through the bypass pipe 13. As a result, the liquid recirculated LNG cooled by the cold box 4 and the liquid recirculated LNG not cooled by the cold box 4 (passed through the bypass circuit 13) are mixed, and the piping 11 and the boil-off gas scatter The temperature of the recirculated LNG supplied to the nozzle 18 can be adjusted. Therefore, the pressure rise in the cargo tank 2 can be suppressed by adjusting the ratio of the cooling of the liquid LNG stored in the cargo tank 2 and / or the reliquefaction of the boil-off gas.

In the pressure rise suppression system (not shown), single-phase (liquid) recirculating LNG is cooled and stored in each cargo tank 2 mounted on a liquefied natural gas carrier (liquefied gas carrier) It was decided to provide the pressure rise suppression device 1 capable of cooling liquid LNG and reliquefying the boil-off gas. Therefore, simplification of the pressure rise suppression system mounted in a liquefied natural gas carrier can be performed, and equipment cost can be reduced.

Second Embodiment In the present embodiment, a flush tank for storing a part of boil-off gas and liquid LNG extracted from the cargo tank is provided, and the liquid LNG extracted from the flash tank is used as a recirculating LNG to the flash tank The second embodiment is the same as the first embodiment in that it circulates. Therefore, about the same structure and suppression method, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
The schematic block diagram of the pressure rise suppression apparatus 51 which concerns on this embodiment is shown by FIG.

As shown in FIG. 6, the LNG recirculation system 60 is provided between the cargo tank (storage tank) 61 provided as a storage tank, and the cargo tank 61 and the cold box (heat exchange means) 4. A flash tank (intermediate tank) 62 and an LNG circulation pump 63 for recirculating liquid LNG (liquefied gas) stored in the flash tank 62 are provided.
In addition. Unlike the case of the first embodiment, the LNG circulation pump 63 of the present embodiment is provided separately from the cargo handling pump for LNG.

The flash tank 62 temporarily stores liquid LNG extracted from the cargo tank 61 and boil-off gas (gaseous LNG) generated in the cargo tank 61.

A portion of liquid LNG is led from the cargo tank 61 by a cargo handling pump not shown, and a boil-off gas stored in the upper space of the cargo tank 61 is led to the flash tank 62.

A portion of the liquid LNG (recirculated LNG) stored in the flash tank 62 is led to the pipe 20 by the LNG circulation pump 63. The liquid recirculating LNG led to the pipe 20 is led to the cold box 4 and the low temperature low pressure nitrogen gas (refrigerant) and heat led from the nitrogen refrigerant cycle 30 in the cooling portion C2 in the cold box 4 Exchange. Thus, the liquid recirculated LNG is cooled and led out to the pipe (supply means) 11.

The cooled liquid recirculated LNG led to the pipe 11 is supplied from the vicinity of the bottom of the flash tank 62 to the liquid LNG stored in the flash tank 62 through the nozzle 18 ′. Thereby, the liquid LNG in the flash tank 62 is cooled by the recirculation LNG.

In addition, a part of the liquid recirculated LNG led to the pipe 11 is led to the upper space of the flash tank 62 and passes through the boil-off gas distribution nozzle (dispersion means) 18 to disperse the boil-off gas in the flash tank 62 Be done. As a result, the boil-off gas in the flash tank 62 is condensed, and the condensed (reliquefied) boil-off gas drops into the liquid phase in the flash tank 62.

Between the cargo tank 61 and the flash tank 62, a liquid transfer pipe 65 for transferring the liquid LNG in the flash tank 62 to the cargo tank 61, and pressurizing the liquid LNG in the cargo tank 61 to flush the liquid tank 62. A liquid pressure transfer pipe 66 for transferring to the lower part of the inside and a gas transfer pipe 67 for transferring boil-off gas in the cargo tank 61 to the upper part in the flash tank 62 are provided.
Thus, the liquid LNG cooled in the flash tank 62 is led from the inside of the flash tank 62 into the cargo tank 61 by the liquid transfer pipe 65. The cooled liquid LNG in the flash tank 62 is introduced from the flash tank 62 into the cargo tank 61, whereby the liquid LNG stored in the cargo tank 61 is cooled. Thereby, the pressure rise in the cargo tank 61 can be suppressed.

As described above, according to the pressure rise suppression device 51 for a cargo tank according to the present embodiment, a pressure rise suppression system including the same, a method of suppressing the same, and the liquefied natural gas carrier including the same, the following effects can be obtained. Play.
A flush tank (intermediate tank) 62 is provided between the cargo tank (storage tank) 61, the cargo tank 61 and the cold box (heat exchange means) 4, and the liquid tank 62 is cooled by the cold box 4. We decided to return circulating LNG (liquefied gas). As a result, even if the capacity of the cargo tank 61 is relatively small, cooling is performed by the cold box 4 without introducing the entire amount of liquid recirculating LNG cooled in the cold box 4 to the cargo tank 61. A portion of the liquid recirculated LNG can be stored in the flash tank 62. Therefore, even if the capacity of the cargo tank 61 is relatively small, the liquid LNG stored in the cargo tank 61 can be cooled to an appropriate temperature.

Further, the pipe (supply means) 11 and the boil-off gas distribution nozzle (dispersion means) 18 are provided in the flash tank 62. Therefore, the boil-off gas distribution nozzle 18 and the LNG circulation pump 63 can be maintained without gas-freeing the cargo tank 61. Therefore, maintenance of the pressure rise suppression device 51 is facilitated.

In addition, the pressure rise suppression system which concerns on this invention is not applied only to a liquefied natural gas carrier, It is applicable also to the liquefied natural gas storage installation (not shown) which stores LNG.

Furthermore, although 1st and 2nd embodiment explained using liquefied natural gas (LNG) as liquefied gas, the present invention is not limited to this, liquefied petroleum gas (LPG) or as liquefied gas, It may be ethane, ethylene, ammonia or a mixture thereof.

In the first and second embodiments, it is described that the liquid recirculated LNG cooled by the cold box 4 is supplied to both the liquid LNG stored in the cargo tank 2 or the flash tank 62 and the boil-off gas. However, it is also possible to supply only one of the liquid LNG and the boil-off gas stored in the cargo tank 2 or the flash tank 62.

In the case of supplying the cooled liquid LNG only to the liquid LNG stored in the cargo tank 2 or the flash tank 62, the temperature of the entire liquid LNG stored in the

cargo tank

2, 61 is supplied. Can be reduced, and boil-off gas can be prevented from being generated from liquid LNG. As a result, the pressure rise in the

cargo tanks

2 and 61 can be suppressed.

In addition, when the liquid recirculating LNG cooled is supplied only to the boil-off gas, re-liquefaction of the boil-off gas is promoted to suppress pressure increase and pressure reduction in the

cargo tanks

2 and 61 by the boil-off gas.

Furthermore, in the first and second embodiments, although the pressure rise suppression system has been described using only one type of LNG as liquefied gas in the plurality of cargo tanks, the cargo tank and the liquefied gas mounted on the liquefied gas carrier are described. It is good also as a pressure rise control system by which a wide variety of different liquefied gas is stored for every cargo tank installed in storage equipment.

In this case, since only the liquid phase (single phase) of the liquefied gas to be recirculated is subjected to heat exchange in the cold box, the pressure difference corresponding to the temperature difference that the nitrogen gas (refrigerant) gives in the cold box is Since it is sufficient to use the compression means for the refrigerant, it is possible to cool various liquefied gases stored in each cargo tank (storage tank) by the pressure rise suppression device 1. Therefore, the pressure rise suppression system can be simplified and the equipment cost can be reduced.

As a pressure rise suppression system capable of cooling a wide variety of liquefied gases stored in each cargo tank by using the pressure rise suppressor of 1, it is possible to use a liquefied gas carrier and a liquefied gas storage facility. The pressure rise suppression system to be mounted can be simplified and the equipment cost can be reduced.

1, 51 Pressure rise suppressor 2 Storage tank (freight tank)
4 Heat exchange means (cold box)
11 Supply means (piping)
13 Bypass means (bypass piping)
15 Bypass flow rate adjustment means (bypass flow control valve)
16 Spreading amount adjustment means (spray control valve)
17 Supply flow rate adjustment means (recirculation control valve)
18 Spraying means (boil off gas spraying nozzle)
31, 32 Compression means for refrigerant (nitrogen compressor, nitrogen booster)
33 Expansion means for refrigerant (nitrogen expander)
61 Storage tank (freight tank)
62 Intermediate tank (flash tank)

Claims

A storage tank storing liquefied gas;
Heat exchange means for exchanging heat between the liquefied gas in a liquid state extracted from the storage tank and the refrigerant;
Refrigerant compression means for compressing the refrigerant introduced to the heat exchange means;
A refrigerant expansion unit that decompresses the refrigerant compressed by the refrigerant compression unit and supplies the refrigerant to the heat exchange unit;
Supply means for supplying the liquid liquefied gas cooled by the heat exchange means to the liquid liquefied gas in the storage tank;
The pressure rise suppression device of the storage tank provided with.
A storage tank storing liquefied gas;
Heat exchange means for exchanging heat between the liquefied gas in a liquid state extracted from the storage tank and the refrigerant;
Refrigerant compression means for compressing the refrigerant introduced to the heat exchange means;
A refrigerant expansion unit that decompresses the refrigerant compressed by the refrigerant compression unit and supplies the refrigerant to the heat exchange unit;
Spraying means for spraying the liquefied gas cooled in the heat exchange means to the gaseous liquefied gas in the storage tank;
The pressure rise suppression device of the storage tank provided with.
A storage tank storing liquefied gas;
Heat exchange means for exchanging heat between the liquefied gas in a liquid state extracted from the storage tank and the refrigerant;
Refrigerant compression means for compressing the refrigerant introduced to the heat exchange means;
A refrigerant expansion unit that decompresses the refrigerant compressed by the refrigerant compression unit and supplies the refrigerant to the heat exchange unit;
Supply means for supplying the liquid liquefied gas cooled by the heat exchange means to the liquid liquefied gas in the storage tank;
Spraying means for spraying the liquid liquefied gas cooled by the heat exchange means to the gaseous liquefied gas in the storage tank;
The pressure rise suppression device of the storage tank provided with.
The pressure rise suppression of the storage tank according to any one of claims 1 to 3, wherein the supply means comprises a supply flow rate adjustment means for adjusting a supply flow rate of the liquefied gas cooled by the heat exchange means. apparatus.
The pressure rise suppression of the storage tank according to any one of claims 2 to 4, wherein the spreading means comprises spreading amount adjusting means for adjusting the spreading amount of the liquefied gas cooled in the heat exchange means. apparatus.
Bypassing a portion of the liquid liquefied gas led to the heat exchange means from the heat exchange means and leading it to the supply means and / or the dispersing means;
Bypass flow rate adjusting means for adjusting a bypass flow rate in which the liquefied gas passes through the bypass means;
The pressure rise suppression device for a storage tank according to any one of claims 1 to 5, comprising:
The storage tank is
Storage tank,
An intermediate tank, provided between the storage tank and the heat exchange means, for temporarily storing the liquefied gas and / or the gaseous liquefied gas extracted from the storage tank ,
The supply means and / or the spreading means are provided in the intermediate tank,
The pressure rise suppression device for a storage tank according to any one of claims 1 to 6, wherein the liquefied gas cooled in the heat exchange means is introduced to the intermediate tank.
A plurality of the storage tanks are provided,
The pressure rise suppression system including the pressure rise suppression device for a storage tank according to any one of claims 1 to 7, wherein the liquefied gas stored in each of the storage tanks is a gas type different for each of the storage tanks. .
A liquefied gas carrier equipped with the pressure rise suppression system according to claim 8.
A liquefied gas storage facility comprising the pressure rise suppression system according to claim 8.
The liquid liquefied gas extracted from the storage tank storing the liquefied gas and the refrigerant compressed after being decompressed are subjected to heat exchange to cool the liquid liquefied gas and cooled by heat exchange. A pressure rise suppression method of a storage tank which leads the liquid liquefied gas to the liquid liquefied gas and / or gaseous liquefied gas stored in the storage tank.