KR20080095391A - Bog treating method - Google Patents

Abstract

A LNG storage tank and LNG transporting method using the same and BOG TREATING METHOD are provided to reduce waste of BOG(Boil Off Gas) in a storage tank. An LNG carrier comprises a BOG treatment unit treating BOG generating in an LNG storage tank The evaporative pressure and the increment of temperature is allowed inside the LNG storage tank. An open and shut pressure value of a safety valve in loading LNG in the LNG storage tank LNG carrier is different when the LNG carrier runs.

Description

ＧＯＧ treatment method {BOG TREATING METHOD}

1 is a view showing the concept of the absorption of heat intake in the LNG storage tank for LNG carriers according to a preferred embodiment of the present invention.

2 is a view schematically showing an LNG storage tank for an LNG carrier according to a preferred embodiment of the present invention.

3 is a view schematically showing a configuration for treating the boil-off gas at the unloading terminal using the LNG storage tank for LNG carriers according to a preferred embodiment of the present invention.

Figure 4 is a schematic diagram showing the waste of the boil-off gas of the LNG carrier ship based on the concept that the pressure of the conventional LNG storage tank is maintained at about the same state.

5 is a schematic diagram showing a pressure operating mode of the LNG storage tank of the LNG carrier according to the tank pressure and flash gas equipment of the LNG unloading terminal.

It is a schematic diagram which shows the method of injecting BOG of LNG tank upper part into LNG of lower part.

<Explanation of symbols for main parts of the drawings>

1 LNG storage tank for LNG carrier 2 LNG storage tank for cargo terminal

3: compressor 4: recondenser

5: carburetor P: high pressure pump

11 LNG pump 13 LNG spray

21: injection nozzle for boil-off gas 23: compressor for boil-off gas

The present invention relates to an LNG carrier having a BOG treatment means for treating boil-off gas (BOG) generated in an LNG storage tank.

In general, natural gas (NG) is produced in the form of liquefied liquefied natural gas (Liquefied Natural Gas, hereinafter referred to as LNG) at the production site, and then transported over a long distance to the destination by LNG carriers. Thereafter, the gas is regasified and supplied to a consumer through an LNG Floating Storage and Regasification Unit (FSRU) or an offshore loading terminal.

When LNG is transported by an LNG Regasification Vessel (RV), LNG is regasified from the LNG Regasification Vessel itself and supplied directly to the consumer without having to go through an LNG floating storage or regasification unit or a land unloading terminal. .

The liquefaction temperature of natural gas is about -163 ° C at ambient pressure, so LNG is evaporated even if its temperature is slightly higher than -163 ° C at normal pressure. For example, in the case of a conventional LNG carrier, the LNG storage tank of the LNG carrier is insulated, but since the external heat is continuously transferred to the LNG, LNG is transported while the LNG carrier is transporting the LNG. Boil-off gas is generated in the LNG storage tank by continuously evaporating in the LNG storage tank.

When the boil-off gas is generated in the LNG storage tank in this way, the pressure of the LNG storage tank rises and becomes dangerous.

Conventionally, in order to maintain the pressure of the LNG storage tank in a safe state, the boil-off gas generated in the LNG storage tank was used as a fuel for propulsion of the LNG carrier. That is, in the case of a LNG carrier that carries LNG in a low temperature liquid state of the related art, the basic concept is that the LNG temperature in the tank is maintained at about the same temperature and the same pressure at around -163 ° C. As a result, the generated BOG was discharged to the outside and treated.

A steam turbine propulsion method driven by steam generated by burning an evaporated gas generated in an LNG storage tank in a boiler has a problem of low propulsion efficiency.

In addition, the dual fuel diesel electric propulsion system, which compresses the boil-off gas generated in the LNG storage tank and uses it as a fuel for a diesel engine, is more efficient than the steam turbine propulsion method, but the medium speed engine and the electric The propulsion device is complex and there are many difficulties in the maintenance of the equipment. In addition, since this method requires the supply of boil-off gas as fuel, a gas compression method having a large installation cost and an operating cost is inevitably applied.

In this case, the method of using the boil-off gas as the fuel for propulsion is, in any case, less than the efficiency of the two-stroke low speed diesel engine used for the general ship.

On the other hand, there is also a way to re-liquefy the boil-off gas generated in the LNG storage tank to return to the LNG storage tank. However, this method of reliquefaction of the boil-off gas has a problem that the LNG carrier to install a boil-off gas reliquefaction device of a complex system.

In addition, when the amount of evaporation gas generated in the propulsion system that can be used as fuel or can be processed by the boil-off gas reliquefaction apparatus is generated, the excess boil-off gas must be incinerated and treated in a gas combustor, so that the treatment of the excess boil-off gas There is a problem in that additional equipment such as a gas burner is added.

For example, as shown in Figure 4, when looking at the LNG carriers based on the basic concept of maintaining the pressure of the conventional LNG storage tank in almost the same state, after the LNG is shipped (3-5 days after shipment) LNG As the storage tank is a little hot, as indicated by the solid upper line, a considerable amount of excess BOG occurs compared to the BOG generation (NBOG, natural BOG) in operation. The fuel consumption of fuel diesel electric propulsion system is more than. Therefore, the BOG corresponding to the hatched portion representing the difference with the lower dotted line showing the amount of BOG used in the boiler or engine is inevitably burned out through the gas combustion unit (GCU). In addition, even when LNG carriers pass through the canal (e.g., 5-6 days in FIG. 4), there is no BOG consumption in the boiler or engine (when waiting for the canal), or less (when passing the canal), so that the BOG more than the engine needs is burned. I have to throw it away. In addition, even when the LNG carrier is waiting to enter or enter the port while the consumption of the BOG occurs or a small amount, there is no choice but to burn the excess BOG.

The amount of BOG ll ride like this when converted to the amount reaches to 1500-2000 tons per year of LNG carriers at 150,000m ³ capacity is equivalent to 600 million won. Furthermore, the burning of BOG also causes environmental pollution.

On the other hand, unlike the low-pressure tank as described above, without forming a thermal insulation wall in the LNG storage tank to maintain a high pressure of about 200 bar (gauge pressure) in the LNG storage tank to suppress the generation of boil-off gas in the LNG storage tank The technique is disclosed in Korean Patent Publication No. KR2001-0014021, KR2001-0014033, KR2001-0083920, KR2001-0082235, KR2004-0015294 and the like. However, in order for the LNG storage tank to receive the boil-off gas at a high pressure of about 200 bar, the thickness of the LNG storage tank must be considerably thick. There is a problem in that separate equipment such as a high pressure compressor for maintaining is added. Unlike this technology, there is a technology known as a pressure tank, which stores a highly volatile liquid in a tank of high temperature at room temperature, so that there is no problem in treating the BOG, but there is a limitation that the size of the tank cannot be increased, and the manufacturing cost thereof There is an increasing problem.

As described above, the LNG tank of the LNG carrier conventionally is a way to maintain the pressure of the cryogenic liquid at a pressure near the normal pressure during transport and to allow the generation of BOG, the consumption of BOG is large or separate reliquefaction There was a problem to mount the device. In addition, unlike the tank for transporting the cryogenic liquid at atmospheric pressure and low pressure, the method of transporting the tank to a tank capable of withstanding high pressure at a somewhat high temperature such as a pressure tank does not have a treatment of BOG, but the size of the tank is limited and manufactured. There is a problem that the cost is high.

Accordingly, the present invention is to solve such a problem of the prior art, and relates to a somewhat high pressure tank near normal pressure for carrying a liquefied gas in a cryogenic state, and it is possible to manufacture a large capacity tank without increasing the manufacturing cost of the tank. It is an object of the present invention to provide an LNG storage tank and a method of transporting LNG using the same or an evaporation gas treatment method using the same, which can reduce BOG waste.

In order to achieve the above object, the present invention relates to a somewhat high pressure tank near normal pressure for carrying a liquefied gas in a cryogenic state, characterized in that it allows a certain pressure change in the tank during transportation.

According to one embodiment of the present invention, in an LNG carrier having a BOG treatment means for treating boil-off gas (BOG) generated in the LNG storage tank, the vapor pressure in the tank and the LNG during the transportation of LNG in the LNG storage tank An LNG carrier and its method are provided for allowing an increase in the temperature of the gas.

As a means for treating BOG, BOG, which is generally generated from LNG storage tanks, is used in boilers (for example, steam turbine propulsion boilers), as a fuel for gas engines such as DFDE or MEGI, in gas turbines, or reliquefaction Is known to return to the LNG storage tank (for example, Korean Patent Publication No. 2004-0046836, Korean Patent Registration 0489804, 0441857, Korean Utility Publication 2006-0000158, etc.). If excess BOG is generated (e.g. after loading LNG), or if it cannot be processed by processing means such as port entry / departure, canal passage, etc., the BOG may be removed by BOG combustion means such as GCU (Gas Combustion Unit). Waste was inevitable.

In the present invention, the flexibility of the BOG process is increased, such BOG waste is removed. The LNG carrier according to the present invention may not require a GCU, and in some cases, a GCU may be required for improving BOG treatment or BOG management flexibility in an emergency.

In the present invention, the LNG carrier is provided with means for discharging and processing BOG from the LNG tank (boiler, reliquefaction apparatus, gas engine, etc.).

According to another embodiment of the present invention, in the control method of the safety valve installed on the upper portion of the LNG storage tank installed in the LNG carrier for transporting the LNG, when the LNG carrier and the LNG carrier Provided is a method for opening and closing a safety valve, wherein the opening and closing pressure values of the safety valve are different at the time of operation. In the present invention, a safety valve, an LNG storage tank, and an LNG carrier are provided.

Conventionally, safety valves were installed on top of storage tanks of LNG carriers transported in cryogenic liquefied natural gas to safely manage the pressure inside the LNG storage tanks. The safety valve ensures stability against explosion of the tank, and the BOG generated after loading LNG is used in boilers (for example, steam turbine propulsion boilers) as above, or as fuel for gas engines such as DFDE and MEGI. Known, used in gas turbines, or liquefied and returned to LNG storage tanks. However, in these methods, when the processing by the processing means is not possible, such as the generation of excess BOG (for example, after loading LNG) or the port entry / departure, the passage of the canal, etc., exceeding the throughput by the usual processing means, the GCU ( Waste of BOG by BOG combustion means such as Gas Combustion Unit is inevitable. In this way, the pressure of the LNG storage tank of the LNG carrier was kept constant within a predetermined range.

Such LNG carriers ship LNG to a volume of about 98% of the LNG storage tank when the safety valve is set at 0.25 bar, leaving the remaining 2% as free space. If more than 98% of the LNG is filled, LNG will overflow from the dome on top of the LNG when the LNG storage tank reaches 0.25 bar. However, when the LNG pressure is continuously allowed to increase after the LNG is shipped as in another embodiment of the present invention, the LNG expands due to the temperature rise of the LNG at the safety valve set pressure according to the present invention even when a small amount of LNG is loaded. As a result, LNG may overflow. For example, when the vapor pressure of the LNG tank is 0.7 bar, it was found that the overflow may occur even when the LNG load is about 97%. This is directly connected to the problem of decreasing LNG load.

Due to this problem, rather than fixedly opening and closing the pressure of the safety valve installed in the upper portion of the LNG storage tank at a relatively high pressure near the normal pressure when loading, it is fixed at a low pressure, such as 0.25 bar, as in conventional LNG carriers, If the amount of LNG in the LNG storage tank is reduced by slightly using BOG (for example, as a fuel in a boiler, engine, etc.), the initial load is decreased by increasing the opening / closing pressure value of the safety valve as in another embodiment of the present invention. This can reduce BOG waste or increase the flexibility of BOG processing. The present invention has a great effect in that there is no waste of BOG when applied to an LNG carrier equipped with means for discharging and processing BOG from an LNG tank (boiler, reliquefaction apparatus, gas engine, etc.).

Therefore, in the present invention, the opening and closing pressure value of the safety valve is raised after the evaporated gas generated in the LNG storage tank is discharged to the outside to reduce the amount of LNG loaded in the LNG storage tank, and preferably to load the LNG. The open / close pressure value at the time of setting is below 0.25 bar, the pressure value at the time of the LNG carrier operation is set at more than 0.25-2 bar, Especially preferably, the pressure value at the time of the LNG carrier is more than 0.25-0.7 bar Is set in. Here, the opening and closing pressure value of the safety valve when the LNG carrier is operating can be increased step by step, for example, 0.4 bar, 0.7 bar according to the amount of use of the boil-off gas according to the operating conditions.

Therefore, when the LNG carrier operates in the present invention means the case where the volume of LNG in the LNG storage tank is somewhat reduced after using the BOG to start the operation after loading the LNG in the LNG carrier. For example, when the volume of LNG is 98.5%, the open / close pressure value of the safety valve is set to 0.25 bar. When the volume of LNG is 98.0%, the open / close pressure value of the safety valve is set to 0.4 bar, and the volume of LNG is 97.6%. It is preferable to set the open / close pressure value of the safety valve to 0.5 bar, and to set the open / close pressure value of the safety valve to 0.7 bar when the volume of LNG is 97.2%.

According to another embodiment of the present invention, in a storage tank of an LNG carrier carrying in a cryogenic liquefied natural gas state, the opening and closing pressure value of the safety valve installed above the storage tank is more than 0.25 to 2 bar, preferably 0.25 It is characterized by setting to more than 0.7 bar, more preferably about 0.7 bar. In the present invention, there is provided a method for opening and closing a safety valve, an LNG storage tank, and an LNG carrier, characterized in that the above configuration.

Such a method has a problem that the loss of BOG and the manufacturing cost of the LNG carrier is increased, in the present invention, the pressure of the LNG storage tank safety valve is increased, so that the pressure inside the tank and the temperature of the LNG are operated after the LNG is shipped from loading to unloading. The above problem was solved by allowing the rise.

 According to another embodiment of the present invention, as a storage tank for LNG carriers carried in the state of cryogenic liquefied natural gas, the steam pressure in the tank is regulated within a pressure range near normal pressure, and the steam pressure and the steam pressure in the tank during transportation of LNG are controlled. An LNG storage tank for an LNG carrier is provided, which allows an increase in the temperature of the LNG. The vapor pressure in the tank is characterized in that more than 0.25 to 2 bar, preferably more than 0.25 to 0.7 bar, more preferably about 0.7 bar. In addition, in order to make the temperature distribution inside the LNG tank uniform, the LNG of the lower portion of the LNG storage tank and the boil-off gas of the upper portion of the LNG storage tank are mixed. Since evaporation of LNG tends to occur more locally at high temperatures in the LNG storage tank, it is desirable to maintain a uniform temperature of LNG or BOG in the LNG storage tank. In addition, from the viewpoint, the boil-off gas in the upper portion of the LNG storage tank has a smaller heat capacity than the LNG in the bottom of the tank, which may cause a sudden increase in pressure due to a rise in temperature due to external inflow heat. As a result, a sudden increase in pressure of the LNG tank can be suppressed.

In addition, according to another embodiment of the present invention, it is possible to adjust the steam pressure in the LNG tank of the LNG carrier according to the pressure of the tank unloaded from the LNG terminal. For example, when the tank pressure at the LNG terminal, LNG-RV, FPSO, etc. to be unloaded is high (for example, around 0.4-0.7 bar), the tank pressure of the LNG carrier is continuously increased and the tank pressure is lowered as before. In the case (about 0.2 bar), the flexibility of the BOG treatment according to the present invention can be used to match the pressure of the tank being unloaded while reducing the BOG waste.

In addition, according to another embodiment of the present invention, there is provided a method for transporting liquefied natural gas in a cryogenic state having the above characteristics and an LNG carrier provided with the tank.

In particular, according to another embodiment of the present invention, the present invention relates to a somewhat high-pressure membrane-type LNG tank near normal pressure that carries a liquefied gas in a cryogenic state, characterized in that it allows a certain degree of pressure change in the tank during transportation. . The membrane tank described in the present invention means a membrane tank defined in the IGC Code (2000) regarding the cargo hold of the LNG tank. Specifically, Membrane tanks are non-self-supporting tanks, which means that a heat insulating wall is formed on the hull and a thin membrane is formed thereon. This includes semi-membrane tanks.

In the following, the tanks described in GTT NO 96, Mark III, Korean Patent Nos. 499710 and 644217 are examples of membrane type tanks.

Such a membrane tank can be designed to withstand up to 0.7 bar (gauge pressure) by reinforcement of the tank, but is generally designed to not exceed 0.25 bar. All conventional membrane-type tanks are in compliance with this regulation and managed so that the vapor pressure inside the tank is 0.25 bar or less, and the temperature and pressure of LNG are almost constant during operation. In contrast, the present invention is characterized in that the management to allow a rise in the tank internal pressure and the temperature of the LNG at a pressure exceeding 0.25 bar, preferably more than 0.25 bar 2 bar or less, more preferably more than 0.25 bar 0.7 bar or less. In addition, the boil-off gas treatment method using the LNG storage tank of the present invention is characterized in that to maintain a uniform temperature distribution inside the LNG storage tank.

According to another embodiment of the present invention, the present invention relates to a large LNG carrier. Preferably it relates to an LNG carrier having an LNG storage capacity of 100,000 m ³ . In order to manufacture LNG tanks into high pressure tanks, LNG carriers of large capacity rapidly increase their manufacturing costs due to the increase in the thickness of the tanks. In addition, LNG can be transported without BOG treatment while substantially supporting the pressure caused by the generation of boil-off gas without significantly increasing.

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

The LNG storage tank of the present invention can be applied to LNG storage tanks such as LNG carriers, LNG floating storage and regasification apparatus (FSRU), land unloading terminal, LNG regasification vessel (RV). As the LNG transport tanks allow for an increase in pressure and temperature while solving the BOG problem, the waste of BOG can be reduced, and LNG can be stored for a long time in the various LNG tanks in consideration of LNG demand at the destination. It also has the advantage of greater flexibility in transportation and storage.

In the present embodiment, the LNG storage tank to be applied to the LNG carrier will be described by way of example.

1 is a view illustrating a concept of absorbing inflow heat in an LNG storage tank for an LNG carrier according to the present invention. In the related art, inlet heat from outside is maintained by maintaining a pressure in a LNG storage tank for an LNG carrier within a predetermined range. While most contribute to the generation of boil-off gas and also process all the boil-off gas generated in the LNG carrier, in the present invention, by allowing the pressure in the LNG storage tank for LNG carriers to rise, the LNG in the tank due to the saturation temperature rise due to the pressure rise Since most of the incoming heat is absorbed by the sensible heat increase of natural gas (hereinafter referred to as NG), the generation of boil-off gas is greatly reduced. For example, when the pressure of the LNG storage tank for LNG carriers is 0.7 bar, the saturation temperature rises about 6 ° C compared to the initial 0.06 bar.

2 schematically shows an LNG storage tank for an LNG carrier according to a preferred embodiment of the present invention. In the case of LNG storage tank (1) for LNG carriers with heat insulation walls, when the LNG is normally loaded, the internal pressure is about 0.06 bar (gauge pressure) at the start, and the evaporation gas is generated during the operation of the LNG carrier. Pressure increases gradually. For example, after loading LNG at the LNG production site, the pressure inside the LNG storage tank 1 for LNG carriers becomes 0.06 bar, and when the LNG carriers start and operate for about 15 to 20 days and arrive at their destinations, the LNG carriers The pressure inside the LNG storage tank 1 can rise to 0.7 bar.

When this is described in relation to temperature, LNG generally contains various impurities and is lower than the boiling point of pure methane liquid. Pure methane has a boiling point of -161. ℃ at 0.06 bar, but LNG transported in LNG transport actually has a boiling point of around -163 ℃ because it contains some impurities such as nitrogen and ethane. In terms of pure methane, the LNG temperature in the tank is around -161 ℃ at 0.06 bar after LNG shipment. If the steam pressure in the tank is controlled at 0.25 bar in consideration of the transport distance and BOG consumption, the LNG temperature is around -159 ℃. If the steam pressure in the tank is controlled to 0.7 bar, the LNG temperature rises to around -155 ° C. If the steam pressure in the tank is controlled to 2 bar, the LNG temperature rises to around -146 ° C.

LNG storage tank for LNG carrier of the present invention is designed in consideration of the pressure rise caused by the generation of the boil-off gas while having a heat insulating wall, that is, it is designed to withstand the pressure rise caused by the generation of boil-off gas. . Therefore, the boil-off gas generated inside the LNG storage tank 1 for LNG carriers during the operation of the LNG carrier is accumulated in the LNG storage tank 1 for the LNG carriers.

For example, the LNG storage tank 1 for LNG carriers according to the embodiment of the present invention is preferably designed to withstand a pressure of more than 0.25 to 2 bar (gauge pressure) with a heat insulating wall, more preferably. It is designed to withstand a pressure of 0.6 to 1.5 bar (gauge pressure). Given the distance of LNG transport and the current IGC Code, it is desirable to be designed to withstand pressures greater than 0.25 bar to 0.7 bar, in particular around 0.7 bar. However, if the pressure is too low, the distance for transporting the LNG is too short, it is not preferable, if too high there is a problem that the production of the tank is not easy.

In addition, the LNG storage tank (1) for LNG carriers according to the present invention is designed to increase the thickness of the initial design, or to add a reinforcement only without adding a reinforcement to the existing LNG storage tanks for general LNG carriers appropriate reinforcement It is economical in terms of production cost because it can be fully realized.

On the other hand, there are various known LNG storage tanks for LNG carriers according to the prior art having a heat insulation (heat dissipation) wall as described below. Therefore, in FIG. 1, illustration of the heat insulation wall is omitted.

First, the LNG storage tank installed inside the LNG carrier can be divided into an independent tank type and a membrane type. The details are as follows.

In Table 1, aka GTT NO 96-2 type and GTT Mark III type were renamed Gaz Transport (GT) and Technigaz (TGZ) in 1995 as GTT (Gaztransport & Technigaz), respectively, GT type was GTT NO 96 -2 type, TGZ type is renamed GTT Mark III type.

GT and TGZ tank structures described above are described in US Pat.

Korean Patent Nos. 499710 and 0644217 disclose a heat insulating wall as another concept.

LNG storage tanks for LNG carriers having various types of insulating walls have been previously disclosed, which are intended to suppress possible vaporization of LNG.

As described above, it is possible to apply the present invention to LNG storage tanks for LNG carriers having various types of thermal insulation functions. Most LNG storage tanks for LNG carriers are designed to withstand a pressure of 0.25 bar or less, and when the pressure reaches or exceeds the pressure of 0.2 bar or less, for example, 0.1 bar, the evaporation gas is consumed as part of the vaporized gas. Or burn everything to the GCU. In addition, a safety valve (safty valve) is installed in the LNG storage tank is discharged to the outside air through a safety valve (usually opening and closing pressure is 0.25 bar) when the above control fails.

On the contrary, in the present invention, a safety valve is installed to control the discharge of the pressure when the pressure rises due to the evaporation gas generated from the LNG storage tank in the upper portion and the normal dome portion of the LNG storage tank of FIG. 2 during the operation of the LNG carrier (not shown). In the present invention, the pressure value of the safety valve is set to more than 0.25 to 2 bar, preferably more than 0.25 to 0.7 bar, more preferably about 0.7 bar.

In addition, the LNG storage tank according to the present invention is configured to reduce the pressure of the LNG storage tank by reducing the local rise in temperature and pressure, thereby reducing the relatively low temperature LNG at the bottom of the LNG storage tank for LNG carriers. LNG carrier for LNG carriers by injecting into the upper part of the LNG storage tank for relatively high temperature LNG carriers and injecting relatively high temperature boil-off gas of the upper part of the LNG carrier tank for LNG carriers to the lower part of the LNG storage tank for LNG carriers that are relatively low temperature. Maintain a uniform temperature distribution in the storage tank.

In FIG. 2, a pump 11 for LNG and an injection nozzle 21 for boil-off gas are provided at a lower portion of the LNG storage tank 1 for an LNG carrier, and a LNG storage tank 1 for an LNG carrier is provided at an upper portion of the LNG storage tank 1 for an LNG carrier. A spray 13 and a compressor 23 for the boil-off gas are provided. Here, the LNG pump 11 and the boil-off compressor 23 can be freely installed at the upper and lower parts. The relatively low temperature LNG in the lower portion of the LNG storage tank 1 for LNG carriers is supplied to the upper LNG spray 13 by the LNG pump 11 so that the LNG storage tank 1 for the LNG carrier is relatively hot. And the relatively high temperature boil-off gas of the upper portion of the LNG storage tank 1 for LNG carriers is supplied to the lower boil-off gas injection nozzle 21 by the boil-off compressor 23 for relatively low temperature. The amount of generation of the boil-off gas can be reduced by spraying the lower portion of the LNG storage tank 1 for LNG carriers and maintaining the temperature distribution of the LNG storage tank 1 for LNG carriers uniformly.

Reducing the amount of boil-off gas is especially useful for LNG carriers without BOG treatment, in order to increase the pressure slowly, since BOG generation is directly related to the pressure increase in the tank.In the case of LNG carriers with BOG treatment means, When the pressure rises, a certain amount of BOG may be discharged to adjust the pressure of the boil-off gas in the tank, so the LNG injection or BOG injection may not be necessary during the operation of the LNG carrier.

In addition, if the LNG is shipped to the LNG carrier in a supercooled state at the production terminal that produces LNG, it is possible to further reduce the boil-off gas (pressure rise) generated during transportation. After loading under supercooling at the production terminal, the LNG storage tank for LNG carriers may be underpressure (0 bar or less), which can be filled with nitrogen to prevent this.

Referring to the method of processing the boil-off gas using the LNG storage tank for LNG carriers as described above are as follows.

When the LNG carrier operates, the LNG storage tank 1 for LNG carrier according to the present invention does not process the boil-off gas, thereby allowing a pressure increase in the tank thereby allowing most of the heat inflow by the internal temperature rise of the tank. Accumulated by the elevated thermal energy of LNG and NG, and when the LNG carrier arrives at the destination, the boil-off terminal processes the boil-off gas accumulated in the LNG storage tank 1 for LNG carrier.

Figure 3 schematically shows a configuration for processing the boil-off gas at the unloading terminal using the LNG storage tank for LNG carriers according to a preferred embodiment of the present invention.

A plurality of LNG storage tanks 2, a high pressure compressor 3a, a low pressure compressor 3b, a recondenser 4, a high pressure pump P and a vaporizer 5 are provided in the cargo terminal.

Since the boil-off gas accumulated in the LNG storage tank 1 for LNG carriers is large, it is usually compressed to 70-80 bar by the high-pressure compressor 3a at the unloading terminal and then supplied directly to the consumer. On the other hand, a part of the boil-off gas accumulated in the LNG storage tank (1) for LNG carriers is usually compressed to around 8 bar by the low pressure compressor (3b) and then recondensed through the recondenser (4) and in the vaporizer (5) It may be vaporized again and supplied to the consumer.

When unloading LNG from LNG storage tank for LNG carrier to LNG storage tank for cargo terminal at the loading terminal, the pressure of LNG storage tank for LNG carrier is greater than the pressure of LNG storage tank for cargo terminal. When high pressure LNG is introduced into the gas, additional boil-off gas is generated.To minimize this, the LNG is directly connected to the inlet of the high-pressure pump at the unloading terminal from the LNG storage tank for the LNG carrier. There is this. LNG storage tank for LNG carrier according to the present invention has the advantage that the unloading time is shortened by 10-20% compared to the conventional LNG carrier because the pressure in the LNG tank is high when unloading.

The LNG stored in the LNG storage tank (1) for LNG carriers is not supplied to the LNG storage tank (2) for the loading terminal of the cargo terminal, but is supplied to the recondenser (4) to recondense the boil-off gas and then vaporize in the vaporizer (5). Can be supplied directly to the consumer.

On the other hand, when the recondenser is not provided in the unloading terminal, LNG can also be supplied directly to the inlet port of the high pressure pump P.

As described above, when a plurality of storage tanks for the cargo terminal 2 are installed in the cargo terminal, the LNG is equalized to the plurality of cargo storage tanks 2 for the cargo terminal from the LNG storage tank 1 for the LNG carrier. When distributed and unloaded, the generation of the boil-off gas is distributed to the plurality of LNG storage tanks 2 of the loading terminal to minimize the influence of the generation of the boil-off gas in the respective LNG storage tanks 2. Since the amount of boil-off gas generated in the storage tank 2 for the unloading terminal is small, it is usually compressed to around 8 bar by the low pressure compressor 3b and then recondensed through the recondenser 4 and vaporized again in the vaporizer 5. And is supplied to the consumer.

In addition, according to the present invention, since the LNG storage tank for LNG carriers is operated above the existing design pressure, to fill the boil-off gas or NG in the LNG storage tanks for LNG carriers to maintain the pressure in the LNG storage tanks for LNG carriers when the LNG unloading The process becomes unnecessary.

In addition, the LNG storage tank for LNG terminal or LNG storage tank for LNG floating storage and regasification unit (FSRU) can be adapted or new LNG terminal LNG so that the storage pressure corresponds to the storage tank pressure for LNG carrier of the present invention. When the LNG storage tank for the storage tank or LNG floating storage and regasification unit (FSRU) is constructed, there is no problem even if the existing unloading method is applied as it does not generate additional boil-off gas during LNG unloading.

According to the present invention, in the case of the LNG floating storage and regasification apparatus (FSRU), since the management flexibility of the boil-off gas is increased, the installation of the recondensation apparatus may be unnecessary.

According to the present invention, the LNG regasification vessel (RV) may have all of the advantages of the aforementioned LNG carrier and the LNG floating storage and regasification apparatus (FSRU).

Figure 5 shows the operating pressure of the LNG storage tank of the LNG carrier according to the tank pressure and the flash gas equipment of the LNG unloading terminal, the F mode LNG carrier if the tank pressure of the unloading terminal is high or has a suitable flash gas treatment equipment Can be operated while increasing the tank pressure. This is particularly useful in LNG carriers that do not have a BOG treatment.

If the unloading terminal tank is low in pressure or the flash gas is not easy to handle, either S or V mode is suitable. Both modes are applicable to LNG carriers with BOG treatment. The S mode is to operate while allowing a constant increase in pressure in the tank of the LNG carrier. The V mode has an advantage of reducing the BOG waste by storing the generated BOG in the LNG storage tank that exceeds the BOG consumption by the BOG treatment means.

While the invention has been described above with reference to specific embodiments, various modifications, changes or modifications may be made in the art within the spirit and scope of the appended claims, and thus, the foregoing description and drawings It should be construed as illustrating the present invention, not limiting the technical spirit of the present invention.

As described above, according to the present invention, an LNG carrier having a BOG treatment means allows an increase in the vapor pressure in the tank and the temperature of the LNG during transportation of LNG in the LNG storage tank, thereby reducing the waste of BOG or Increased flexibility

In particular, according to the present invention, even if the amount of boil-off gas generated during transportation of LNG is more than the consumption amount can be preserved without loss of the boil-off gas, bringing economical efficiency and efficiency. For example, in the case of an LNG carrier equipped with an engine for treating boil-off gas as shown in FIG. 4, an excess occurrence that occurs several days after shipment of LNG occurs during passage of a canal or during arrival of a canal or during arrival of a port or when entering a port The BOG more than the engine consumption to be burned off in the past using a GCU in most cases, but by applying the technology of the present invention can reduce the waste of such BOG.

 In addition, when a gas / liquid combined engine is used in an LNG carrier, fuel can be supplied using a liquid pump instead of an evaporative gas compressor, thereby greatly reducing installation and operating costs.

Claims (1)

A method for treating boil-off gas (BOG) generated in large LNG storage tanks carrying cryogenic LNG.

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