KR20120126998A - Apparatus of storing container for liquefied natural gas - Google Patents

Abstract

PURPOSE: A LNG storage container structure is provided to have structural stability and durability by preventing stress concentration because an inner shell and an outer shell are slidingly connected to absorb the deformation of the inner shell due to the loads and temperatures. CONSTITUTION: A LNG storage container structure comprises an inner shell(1110), an outer shell(1120), an insulation layer part(1150), and protrusion supports(1130). LNG is stored inside the inner shell. The outer shell surrounds the exterior of the inner shell to form a space between the inner and outer shells. The insulation layer part is installed in the space between the inner and outer shells and reduces heat transfer. The protrusion supports are protruded from the exterior of the inner shell and the interior of the outer shell.

Description

Structure of liquefied natural gas storage container {APPARATUS OF STORING CONTAINER FOR LIQUEFIED NATURAL GAS}

The present invention relates to a structure of a liquefied natural gas storage container, which can efficiently supply liquefied natural gas as well as liquefied natural gas pressurized at a constant pressure and supply it to a consumer, and minimizes the use of a metal having excellent low-temperature characteristics, thus producing costs. It relates to a structure of a liquefied natural gas storage container having a sliding structure configured to reduce the cost.

In general, liquefied natural gas (LNG) is a colorless transparent cryogenic liquid whose natural gas containing methane as its main component is cooled to cryogenic condition at -162 ℃ at atmospheric pressure, and its volume is reduced to one hundredth. It is known that it is economical for long distance transportation because it has better transport efficiency than gas state.

Such liquefied natural gas has been applied to large-scale and long-distance transportation in order to satisfy economic feasibility due to the high cost of construction of the production plant and the construction of carriers, whereas pipelines or compressed natural gas (CNG) for small- and short-haul transportation have been applied. Although it is known to have economic feasibility, transportation by pipelines is subject to geographical constraints, may cause problems of environmental destruction, and CNG has a disadvantage of low transportation efficiency.

The conventional method of distributing liquefied natural gas to consumers requires not only high costs, but also it is difficult to flexibly cope with various demands of the consumers, and requires a separate storage tank at the site, which requires a large amount of investment in infrastructure. Unloading gas also had a problem that requires a lot of time and effort.

In addition, natural gas has a liquefaction point of -163 ℃ at atmospheric pressure, when a certain pressure is applied has a characteristic that the liquefaction point rises under atmospheric pressure. This characteristic can reduce the processing steps such as removal of acid gas and fractionation of natural gas liquid (NGL) during the liquefaction process, which leads to a reduction in equipment and equipment capacity. It has the advantage of reducing the production cost of.

However, the liquefied natural gas storage tank provided in a conventional liquefied natural gas terminal or a vessel equipped with a gasification facility is not only limited to a certain size, but also liquefied natural gas which has economical characteristics by reflecting the characteristics of the natural gas as described above. It is difficult to transport liquefied natural gas to the consumer, which is inadequate for the storage, and to meet the needs of various consumers.

In order to solve the above problems, in order to store not only general liquefied natural gas but also liquefied natural gas pressurized at a constant pressure, a container is made to withstand cryogenic and high pressure of -120 ° C or more by using a metal material having excellent low temperature characteristics. This is possible, but for this purpose, the wall thickness of the container is inevitably increased, and there is another problem of difficulty in securing economic feasibility due to the use of expensive metal having excellent low temperature characteristics.

The present invention is to solve the conventional problems as described above, liquefied natural gas as well as liquefied natural gas pressurized at a constant pressure can be efficiently stored and supplied to the consumer, and minimize the use of metal with excellent low-temperature characteristics It is possible to reduce the production cost, to easily meet the needs of various purposes and consumers, and to ensure the variety of types and sizes of transport vessels.

According to an aspect of the present invention for achieving the above object, in the structure of the liquefied natural gas storage container, the inner shell (1110) is stored inside the liquefied natural gas; An outer shell 1120 surrounding an outer side of the inner shell 1110 to form a space between the inner shell 1110; installed in a space between the inner shell 1110 and the outer shell 1120, A heat insulation layer portion 1150 to reduce heat transfer; And a protrusion support 1130 formed to protrude into the space on the outside of the inner shell 1110 and the inside of the outer shell 1120, wherein the protruding ends of the protrusion support 1130 face each other. It has a photographic cross section; provides a structure of a liquefied natural gas storage container. .

The protruding support 1130 is provided with a plurality of intervals in any one or more of the longitudinal direction and the circumferential direction of the storage container 1100;

The protruding support 1130 may include a lower support block 1131 having an inclined upper end surface; And an upper support block 1132 having an inclined lower end surface, wherein the lower end surface of the upper support block 1132 moves on an upper end surface of the lower support block 1131.

A plurality of grooves are formed in the upper end surface or the lower end surface.

The protruding support 1130 may further include a sliding member 1133 formed on a lower end surface of the upper support block 1132 or an upper end surface of the lower support block 1131.

The sliding member 1133 may include a spring or a roller.

The inner shell 1110 is made of a metal that withstands the low temperature of the liquefied natural gas, the outer shell 1120 is made of a steel (steel) material to withstand the internal pressure;

The inner shell 1110 withstands a temperature of -120 ~ -95 ℃, the outer shell 1120 withstands a pressure of 13 ~ 25bar;

A space between the inner shell 1110 and the outer shell 1120 of the storage container such that the pressure between the inner shell 1110 and the outer shell 1120 of the storage container and the pressure of the inner shell 1110 are balanced. It is characterized in that it comprises a; a coupling flow path installed between the inner shell (1110).

According to another aspect of the present invention, in the structure of the liquefied natural gas storage container, an insulating layer portion for reducing heat transfer is provided between the inner shell in which the liquefied natural gas is stored and the outer shell surrounding the outer side of the inner shell, And an outer surface of the inner shell and an inner surface of the outer shell are supported by each other by a separated protruding member to have an inclined cross section.

According to the present invention, the liquefied natural gas, as well as the liquefied natural gas pressurized at a constant pressure can be efficiently stored and supplied to the consumer, and the production cost can be reduced by minimizing the use of metal having excellent low temperature characteristics, and various purposes and It is possible to easily meet the needs of the consumer, and to ensure the variety of types and sizes of transport vessels.

In addition, the internal pressure of the inner shell and the internal pressure of the insulation layer are designed to have a similar value to ensure structural safety, and the outer shell is used as a steel material that can withstand the internal pressure, thereby reducing the use of metal having excellent low-temperature characteristics. You can save money.

In addition, by connecting the inner shell and the outer shell in a sliding structure to absorb the deformation caused by the load and temperature changes caused by the inner shell can prevent the stress concentration can ensure structural stability and durability.

In addition, the volume of the support can be reduced compared to the conventional volumetric support structure, so that the insulation material can be increased by that much, the insulation performance can be improved.

In addition, since the area of the contact surface in which the sliding occurs can be widened, support for the height direction and the radial direction of the storage container can be simultaneously performed, and the support area can be easily enlarged.

1 is a flow chart showing a pressurized liquefied natural gas production method according to the present invention,
Figure 2 is a block diagram showing a pressurized liquefied natural gas production system according to the present invention,
3 is a flowchart illustrating a pressurized liquefied natural gas distribution method according to the present invention;
4 is a configuration diagram for explaining a pressurized liquefied natural gas distribution method according to the present invention;
Figure 5 is a side view showing a pressure vessel used in the pressurized liquefied natural gas distribution method according to the present invention,
6 is a configuration diagram for explaining another example of the pressurized liquefied natural gas distribution method according to the present invention;
7 is a perspective view showing a storage tank of liquefied natural gas according to the present invention;
8 is a perspective view showing various specifications for the storage tank of liquefied natural gas according to the present invention;
9 is a block diagram showing a storage tank of liquefied natural gas according to the present invention,
10 is a configuration diagram showing another example of a liquefied natural gas storage tank according to the present invention,
11 is a cross-sectional view showing a storage container of liquefied natural gas according to the first embodiment of the present invention;
12 is a cross-sectional view showing another embodiment of the connecting portion formed in the storage container of liquefied natural gas according to the first embodiment of the present invention;
13 is a cross-sectional view for explaining the operation of the storage container of liquefied natural gas according to the first embodiment of the present invention;
14 is a partial cross-sectional view showing a storage container of liquefied natural gas according to a second embodiment of the present invention;
15 is a partial cross-sectional view showing a storage container of liquefied natural gas according to a third embodiment of the present invention;
16 is a cross-sectional view showing a storage container of liquefied natural gas according to a fourth embodiment of the present invention;
17 is a cross-sectional view taken along the line AA ′ of FIG. 16;
18 is a cross-sectional view taken along line BB ′ of FIG. 17;
19 is a cross-sectional view showing a storage container of liquefied natural gas according to a fifth embodiment of the present invention;
20 is a cross-sectional view showing a storage container of liquefied natural gas according to a sixth embodiment of the present invention;
FIG. 21 is a cross-sectional view taken along the line CC ′ of FIG. 20;
22 is a cross-sectional view showing a storage container of liquefied natural gas according to a seventh embodiment of the present invention;
23 is a block diagram showing a storage container of liquefied natural gas according to an eighth embodiment of the present invention;
24 is a configuration diagram showing a storage container of liquefied natural gas according to a ninth embodiment of the present invention;
25 is a configuration diagram showing a storage container of liquefied natural gas according to a tenth embodiment of the present invention;
26 is a cross-sectional view showing a storage container of liquefied natural gas according to an eleventh embodiment of the present invention;
27 is a cross-sectional view showing another example of a connection portion of a storage container of liquefied natural gas according to an eleventh embodiment of the present invention;
28 is a cross-sectional view showing still another example of a connection portion of a storage container of liquefied natural gas according to an eleventh embodiment of the present invention;
29 is a cross-sectional view showing another example of a connection portion of a storage container of liquefied natural gas according to an eleventh embodiment of the present invention;
30 is an enlarged view illustrating main parts of a storage container of liquefied natural gas according to a twelfth embodiment of the present invention;
31 is a perspective view illustrating a buffer unit provided in a storage container of liquefied natural gas according to a twelfth embodiment of the present invention;
32 is a perspective view illustrating another example of a buffer unit provided in a storage container of liquefied natural gas according to a twelfth embodiment of the present invention;
33 is a block diagram showing an apparatus for producing liquefied natural gas according to the present invention;
34 is a side view showing a floating structure having a storage tank conveying device according to the present invention;
35 is a front view showing a floating structure having a storage tank conveying device according to the present invention;
36 is a side view for explaining the operation of the floating structure having a storage tank transport apparatus according to the present invention;
37 is a block diagram showing a high pressure maintaining system of the pressurized liquefied natural gas storage container according to the present invention;
38 is a block diagram showing a heat exchanger separate type liquefaction apparatus according to a first embodiment of the present invention;
39 is a block diagram showing a separate heat exchanger type liquefaction apparatus according to a second embodiment of the present invention;
40 is a sectional front view showing a liquefied natural gas storage container carrier according to the present invention,
41 is a side sectional view showing a LNG storage container carrier in accordance with the present invention;
42 is a plan view showing a main portion of a LNG storage container carrier according to the present invention;
43 is a block diagram showing a carbon dioxide solidification removal system according to the present invention,
44 is a view showing the operation of the carbon dioxide solidification removal system according to the present invention,
45 is a cross-sectional view showing a connection structure of a liquefied natural gas storage container according to the present invention;
46 is a perspective view showing a connection structure of a liquefied natural gas storage container according to the present invention;
47 is a cross-sectional view for explaining the operation of the connection structure of the LNG storage container according to the present invention.
48 is a view schematically showing a storage container of liquefied natural gas according to the present invention.
49 is a view schematically showing the structure of a storage vessel inner shell of liquefied natural gas according to the present invention.
50 is a view showing the various forms of the structure of the inner shell of the storage vessel of the liquefied natural gas according to the present invention.
51 is a view showing the various forms of the structure of the inner shell of the storage vessel of the liquefied natural gas according to the present invention.
52 is a view schematically showing the structure of an inner shell of a storage container of liquefied natural gas according to the present invention.
53 is a view schematically showing a storage container of liquefied natural gas according to the present invention.
54 is a view schematically showing the structure of a liquefied natural gas storage container according to the present invention.
55 to 57 is a view schematically showing a hinge support of the liquefied natural gas storage container according to the present invention, (a) is a plan view, (b) is a side view.
58 is a view schematically showing the structure of a liquefied natural gas storage container according to the present invention.
59 is a view schematically showing the structure of a liquefied natural gas storage container according to the present invention.
60 is an enlarged view of a portion A of FIG. 59, (a) is a view when the inner shell is expanded, and (b) is a view when the inner shell is contracted;
61 is a view schematically showing the structure of a liquefied natural gas storage container according to the present invention, (a) is a view showing two lower supports, (b) is a view showing a cross-sectional view.
62 is a view schematically showing the structure of a liquefied natural gas storage container according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, the following examples can be modified in various forms, and the scope of the present invention is not limited to the following examples.

In the drawings, like reference numerals refer to like elements throughout. The same reference numerals in the drawings denote like elements throughout the drawings.

1 is a flow chart illustrating a pressurized liquefied natural gas production method according to the present invention.

As shown in Figure 1, the pressurized liquefied natural gas production method according to the present invention is dehydrated without removing the acid gas from the natural gas supplied from the natural gas field (1), the natural gas is NGL (Natural Gas Liquid) Liquefaction is produced by pressure and cooling without fractionation to produce a pressurized liquefied natural gas, which may include a dehydration step (S11) and a liquefaction step (S12).

According to the dehydration step (S11), the natural gas is supplied from the natural gas field 1 to remove moisture such as steam by dehydration without the process of removing the acid gas. Therefore, natural gas may be dehydrated without undergoing acid gas removal, thereby simplifying the process and reducing investment and maintenance costs by eliminating acid gas removal. In addition, by sufficiently removing the water from the natural gas by the dehydration step (S11) to prevent the water freezing of the natural gas at the operating temperature and pressure of the production system.

According to the liquefaction step (S12), the natural gas after the dehydration step (S11) is liquefied to a pressure of 13 ~ 25bar and a temperature of -120 ~ -95 ℃ without the process of fractionating the Natural Gas Liquid (NGL) It will produce a liquefied natural gas, for example, can produce a pressurized liquefied natural gas having a pressure of 17 bar and a temperature of -115 ℃. Therefore, it is possible to simplify the production process of liquefied natural gas by omitting the fractionation process for NGL, that is, liquefied hydrocarbons, against natural gas, as well as to reduce power consumption for cooling and liquefying natural gas at a cryogenic temperature, And the maintenance cost can be reduced, thereby lowering the unit cost of the liquefied natural gas.

In the method of producing pressurized liquefied natural gas according to the present invention, the condition of the natural gas field 1 may be such that the calculated natural gas has less than 10% of carbon dioxide (CO ₂ ). In addition, when the carbon dioxide is present in less than 10% in the natural gas after the dehydration step (S11) may further include a carbon dioxide removal step (S13) for freezing and removing the carbon dioxide in the liquefaction step.

Carbon dioxide removal step (S13) may be carried out when the carbon dioxide in the natural gas after the dehydration step (S11) is more than 2% or less than 10%. Here, since natural gas exists in a liquid state at the temperature and pressure conditions of the pressurized liquefied natural gas which will be described later when carbon dioxide is 2% or less, the production and transportation of the pressurized liquefied natural gas are not affected even if the carbon dioxide removal step (S13) is not performed. If the carbon dioxide is more than 2% and less than 10% is frozen as a solid, the carbon dioxide is removed (S13) for liquefaction.

After the liquefaction step (S12), the storage step (S14) for storing the pressurized liquefied natural gas produced by the liquefaction step (S12) in a storage container of a dual structure can be carried out, whereby the pressurized liquefied natural gas is a desired position To this end, the transfer step (S15) may be carried out to transport through the vessel to the individual or packaged storage containers for this purpose. Of course, the strength of the tank may be transported through the vessel in a separate or packaged storage container for LNG transport.

Storage container used in the transfer step (S15) may have a material and structure to withstand the pressure of 13 ~ 25bar and the temperature of -120 ~ -95 ℃. In addition, a vessel for transporting a storage container may reduce a cost required for transporting a storage container by using a barge or a container ship without using a separate ship, such as a LNG carrier.

In this case, a barge or a container ship may be loaded and transported as it is or with minimal modification. Here, the storage vessels carried by the vessel may be transported in individual storage vessel units as required by the consumer.

On the other hand, the pressurized liquefied natural gas stored in the storage container supplied to the demand by completing the transfer step (S15) is to be supplied to the natural gas in the gas state through the regasification step (S16) at the final consumer. Here, the regasification facility for performing the regasification step (S16) may be composed of a high-pressure pump and a carburetor, in the case of individual unit consumption, such as power plants or factories may be provided with their own regasification facilities.

Figure 2 is a block diagram showing a pressurized liquefied natural gas production system according to the present invention.

As shown in Figure 2, the pressurized liquefied natural gas production system 10 according to the present invention is a natural dehydration equipment (11) for receiving and dehydrating natural gas supplied from the natural gas field (1), and natural through the dehydration equipment (11) It may include a liquefaction facility 12 for producing a pressurized liquefied natural gas by liquefying the gas at a pressure of 13 ~ 25bar and a temperature of -120 ~ -95 ℃.

The dehydration facility 11 receives natural gas from the natural gas field 1 to remove moisture such as water vapor by a dehydration process, thereby preventing freezing of natural gas at the operating temperature and pressure of the production system. At this time, the natural gas supplied from the natural gas field 1 to the dehydration facility 11 does not go through the process of removing acid gas, thereby simplifying the liquefied natural gas production process and investing and maintaining it. Help reduce costs

The liquefaction facility 12 is to liquefy the natural gas passed through the dehydration facility 11 at a pressure of 13 ~ 25bar and a temperature of -120 ~ -95 ℃ to produce a pressurized liquefied natural gas, for example a pressure of 17bar and -115 It may be to produce a pressurized liquefied natural gas having a temperature of ℃, it may include a compressor and a cooler required for the compression and cooling of low temperature fluid. Here, the natural gas that has passed through the dehydration facility (11) is supplied to the liquefaction facility (12) without the process of fractionating the NGL (Natural Gas Liquid) is passed through the liquefaction step, which is due to the fractionation process for NGL, ie liquefied hydrocarbons This reduces the cost of manufacturing and maintaining the system, thereby lowering the cost of liquefied natural gas.

The pressurized liquefied natural gas production system 10 according to the present invention removes carbon dioxide provided to freeze and remove carbon dioxide from natural gas when carbon dioxide is less than 10% in natural gas that has passed through the dehydration facility 11. It may further comprise a facility (13).

The carbon dioxide removal system 13 may perform removal of carbon dioxide from natural gas only when carbon dioxide exceeds 2% or 10% or less in the natural gas that has passed through the dehydration facility 11. In other words, natural gas exists in a liquid state at the temperature and pressure conditions of pressurized liquefied natural gas when carbon dioxide is 2% or less, so it is unnecessary to remove carbon dioxide, and carbon dioxide is frozen as a solid when carbon dioxide is more than 2% and 10% or less. It is necessary to remove carbon dioxide by the removal facility 13.

The pressurized liquefied natural gas produced from the liquefaction facility 12 is stored in a storage container of a dual structure in the storage facility 14 and transferred to a desired consumer by transport of the storage container.

3 is a flowchart illustrating a pressurized liquefied natural gas distribution method according to the present invention.

As shown in FIG. 3, the method for distributing a pressurized liquefied natural gas according to the present invention loads a storage container in which a pressurized liquefied natural gas liquefied by applying pressure to a natural gas and cools it, and transports the vessel to a consumer. The container is unloaded to the consumer and then the storage container is connected to the consumer regasification system. To this end, the pressurized liquefied natural gas distribution method according to the present invention may include a transfer step (S21), an unloading step (S22), and a connection step (S23).

As shown in Figure 4, according to the transfer step (S21), the pressurized liquefied natural gas liquefied natural gas at a pressure of 13 ~ 25bar and a temperature of -120 ~ -95 ℃ is stored and transportable container ( 21) is loaded on the vessel (2) to be transported to the consumer (3). Here, the pressurized liquefied natural gas may be produced by the above-described method of producing the pressurized liquefied natural gas, and the storage container 21 storing the same may use a natural gas at a pressure of 13 to 25 bar and a temperature of -120 to -95 ° C. With a material and structure that can withstand, it can be made of a double structure, and can be loaded in a large number on the vessel (2).

The transporting step S21 can transport the storage container 21 by a land transportation means such as a trailer or a train when the consumable product 3 is located inland.

The unloading step S22 is a step of unloading the storage container 21 filled with the pressurized liquefied natural gas by the unloading facility to the consumable paper when the ship 2 arrives at the consumable paper 3, As shown in FIG.

The connecting step S23 is a step of connecting the storage container 21 to the regasification system 23 of the consumer paper 3 so that the pressurized liquefied natural gas stored in the storage container 21 is vaporized. The natural gas generated by vaporizing the pressurized liquefied natural gas can be supplied to the consumer 3a. Meanwhile, as shown in FIG. 5, the storage container 21 is provided with a nozzle 21a for connecting to the vaporization line of the pressurized liquefied natural gas and the regasification system 23. Here, the nozzle 21a may be provided in various structures at various positions according to the posture in which the storage container 21 is loaded on the vessel 2 and the posture connected to the regasification system 23. It may have a connector that may be connected to the connector of the storage facility and the regasification system 23.

The distribution method of pressurized liquefied natural gas according to the present invention may further include a recovery step (S24) for recovering the empty storage container 21 from the consumption place (3).

Recovery step (S24) is to save the logistics cost by allowing the empty storage container 21 to be recovered to the place where the pressurized liquefied natural gas production system 10 is located by using the land transport means or the vessel (2), thereby natural gas May contribute to lowering the supply cost of

As shown in FIG. 6, in the transferring step S21, the container assembly 22 having a plurality of storage containers 21 packaged together may be transferred. Here, the container assembly 22 may be provided with an integrated nozzle 22a connected to each of the storage containers 21 to unify the nozzle 21a (shown in FIG. 5) provided for access of the pressurized liquefied natural gas. Therefore, the storage container 21 is configured by the container assembly 22 in a bundle unit, and the loading and unloading step S22 in the transfer step S21 by using the integrated nozzle 22a as a single container. It can reduce the time and effort required for unloading in the connection, connection with the regasification system 23 in the connection step (S23), and recovery in the recovery step (S24).

In the case of the container assembly 22, the storage container 21 is made up of a large number, so that it is efficient to be unloaded and used where a large amount of natural gas is required as a single consumption place, such as a power plant or an industrial complex.

In addition, according to the distribution method of the pressurized liquefied natural gas according to the present invention, there is an advantage that a separate storage tank is not required at the consumption place. In addition, only the regasification system needs to be provided, and the container 21 or the storage vessel 21 is circulated from the place where the pressurized liquefied natural gas production system 10 is located to each individual consumption place 3 by the vessel or the land transportation means in parallel with the vessel. The business of unloading the container assembly 22 and recovering the empty storage container 21 or the container assembly 22 is enabled. In particular, when a large number of small and medium-sized consumers are distributed on a large number of islands, such as Southeast Asia, it is possible to minimize the construction of infrastructure such as separate storage facilities and pipelines.

7 is a perspective view showing a storage tank of liquefied natural gas according to the present invention.

As shown in Figure 7, the storage tank 30 of the liquefied natural gas according to the present invention is provided with a plurality of storage containers 32 for storing the liquefied natural gas, respectively, inside the main body 31, the storage container (32) The loading and unloading of the liquefied natural gas to the storage container 32 is made possible through the loading and unloading line 33 which is connected to each and is provided with the loading and unloading valves 33a and 33b.

The main body 31 is provided so that a plurality of storage containers 32 are arranged inside, and the spacers 31a are installed between the storage containers 32 so that the storage containers 32 maintain the arrangement state while maintaining a space therebetween. ) May be included.

In addition, the main body 31 may have a heat insulating layer for blocking the entry and exit of temperature, or may have a double structure for heat insulation, may be made of a hexahedral structure, or in various other structures as in the present embodiment. In addition, the main body 31 may be provided with a plurality of support (31b) on the bottom in order to block the heat transfer of the ground by being spaced apart from the ground and to be installed in a stable posture on the ground.

As shown in Fig. 8, the main body 31 has a large, medium and small size standard as in (a), (b), (c) to standardize the number and size of the storage containers 32. In addition, the present invention is not limited thereto, and may accommodate various numbers of storage containers 32 and may be manufactured in various standards.

Storage container 32 may be made of a structure or material that withstands a pressure of 13 ~ 25bar and a temperature of -120 ~ -95 ℃ with a loading and unloading line 33 to be described later to be stored liquefied natural gas, respectively. Therefore, the storage container 32 and the unloading line 33 has a double structure, such as a heat insulating material is installed to withstand such pressure and temperature conditions, the pressure of 13 ~ 25bar and the temperature of -120 ~ -95 ℃, For example, it enables the storage and transportation of pressurized liquefied natural gas having a pressure of 17 bar and a temperature of -115 ° C.

As shown in FIG. 9, the loading and unloading line 33 is connected to each of the storage containers 32 and extends to the outside of the main body 31, so that the loading and unloading of the liquefied natural gas to the storage container 32 is performed. Unloading valves 33a and 33b for opening and closing are provided. Therefore, after the main body 31 is installed in the consumer place, when the loading and unloading line 33 is connected to the regasification system, supply line, etc. of the consumer place, supply of liquefied natural gas or natural gas is immediately possible.

Here, the unloading valves 33a and 33b are provided to the first individual valve 33a and the storage container 32 all individually installed to open and close the loading and unloading of the liquefied natural gas to each of the storage containers 32. It may include a first integrated valve 33b which is installed to open and close the unloading and unloading of the natural liquefied natural gas, each storage container is one if the first individual valve 33a is opened as the unloading valve It can also be packaged into a single tank. Moreover, only the 1st individual valve 33a may be provided, or only the 1st integrated valve 33b may be provided and used.

The storage tank 30 of the liquefied natural gas according to the present invention is connected to some or all of the storage container 32 to the outside of the main body 31 for the discharge of naturally occurring boil-off gas from the storage container 32. In addition to the elongated installation, it may further include an evaporation gas line 34 is provided with the evaporation gas valve (34a, 34b) for opening and closing the discharge of the boil-off gas (BOG) generated in the storage container (32). Here, the boil-off gas line 34 may be made of a structure or material that withstands a pressure of 13 ~ 25bar and a temperature of -120 ~ -95 ℃.

In addition, the boil-off gas valves 34a and 34b are second individual valves 34a that are individually installed to open and close the discharge of the boil-off gas to each of the storage containers 32 and the boil-off gas to all the storage containers 32. It may include a second integrated valve 34b which is installed to open and close the discharge of the integrated, only the second individual valve 34a, or only the second integrated valve 34b may be installed as the boil-off gas valve. . Here, as described above, if all of the second individual valves 34a are opened, each storage container may be packaged as one and may be used as one tank. Also, only the second individual valve 34a may be installed, or only the first integrated valve 34b may be installed and used.

The storage tank 30 of the liquefied natural gas according to the present invention measures the internal pressure for each or all of the storage containers 32 and outputs it from the pressure sensing unit 35 and the pressure sensing unit 35 to output the detection signal. The controller 36 may further include a controller 36 configured to receive the detection signal and to display the internal pressure for each or all of the storage containers 32 to the outside of the main body 31 through the display unit 37. Here, the pressure sensing unit 35 is installed at the front end of the storage container 32 in the loading and unloading line 33, respectively, for example, in order to measure the internal pressure for each or all of the storage containers 32, or the loading and unloading line. In (33) it may be installed on an integrated route which travels for the loading and unloading of liquefied natural gas. In addition, the control unit 36 is provided on the main body 31 or the unloading valves 33a and 33b and the boil-off gas valves 34a, in accordance with an operation signal output from the operation unit 36a provided for wired and wireless communication at a remote location. 34b) can be controlled respectively.

As shown in FIG. 10, the storage tank 30 of the liquefied natural gas according to the present invention is used to control the heating value required in the vaporization and consumption of the liquefied natural gas discharged from the storage container 32. Heating unit 38 is installed to vaporize the liquefied natural gas unloaded from some or all of the storage container 32, and the calorific value control unit 39 is installed to adjust the calorific value of the natural gas passing through the heating unit 38 It may include. Here, the heating unit 38 and the calorific value control unit 39 are installed on a line in which any one or many of the storage containers 32 are integrated in the loading and unloading line 33, or the storage container 32 and the loading and unloading unit. Connected to the line 33 may be installed in a separate line to pass the liquefied natural gas by the valve.

The heating unit 38 is a plate fin type heat exchanger 38a which is installed to primarily heat the liquefied natural gas by heat exchange with air, and the liquefied natural gas vaporized by passing through the heat exchanger 38a. It may include an electric heater 38b that is installed to heat differentially.

The line where the calorific value control unit 39 is installed, for example, the loading and unloading line 33, may further include a bypass line 41 connected to bypass the calorific value control unit 39 by the bypass valve 41a. have. Therefore, when it is necessary to adjust the calorific value for the natural gas, the natural gas is supplied to the calorific value control unit 39 by the operation of the bypass valve 41a so that natural gas having the calorific value required by the consumer is supplied, When it is unnecessary to adjust the amount of heat generated for the gas, the natural gas may bypass the heat amount adjusting unit 39 through the bypass line 41 by the operation of the bypass valve 41a. Here, the bypass valve 41a may be composed of a three-way valve or a plurality of bidirectional valves.

In addition, the storage tank 30 of the liquefied natural gas according to the present invention has a temperature sensing unit 42 for sensing the temperature of the natural gas to be unloaded, so that the natural gas to be unloaded has a temperature required by the consumer, and the temperature The controller 36 may further include a controller 36 that receives the signal from the detector 42 and controls the electric heater 38b to reach the set temperature range. The controller 36 may display the temperature of the natural gas being unloaded to the outside of the main body 31 through the display unit 37.

The temperature sensing unit 42 may be installed at the exit side of the loading and unloading line 33. In addition, the controller 36 may control the bypass valve 41a described above according to the operation signal of the operation unit 36a.

As described above, the storage tank 30 of the liquefied natural gas according to the present invention has a storage container 32 capable of storing and treating boil-off gas according to a function, and a storage container capable of controlling vaporization facilities and calorific value as well as storing and treating boil-off gas. It can be divided into (32), allowing easy transport of liquefied natural gas or natural gas to meet the consumer's needs.

11 is a cross-sectional view showing a storage container of liquefied natural gas according to the first embodiment of the present invention.

As shown in FIG. 11, the storage container 50 of the liquefied natural gas according to the first embodiment of the present invention includes an inner shell 51 and an inner shell made of a metal that withstands low temperature of the liquefied natural gas stored therein. A heat insulation layer portion 53 may be installed to reduce heat transfer between the outer shells 52 made of a steel material to withstand the inner pressure by wrapping the outer side of the 51.

The inner shell 51 forms a space for storing liquefied natural gas inside, and has a low temperature property such as aluminum, stainless steel, 5-9% nickel steel, etc. It may be made in the form of a tube, as in the present embodiment, or may have various shapes including other polyhedrons.

The outer shell 52 surrounds the outside of the inner shell 51 to form a space between the inner shell 51 and is made of a steel material to withstand the internal pressure, and is applied to the inner shell 51. By reducing the internal pressure of the paper to reduce the use of the inner shell 51 material to reduce the manufacturing cost.

Since the inner shell 51 is equal to or close to the pressure of the inner shell and the heat insulating layer by the connection flow path to be described later, the pressure of the liquefied natural gas can be supported by the outer shell. Thus, even if the inner shell 51 is manufactured to withstand temperatures of -120 to -95 ° C, the above-described pressure (13-25 bar) and temperature conditions by the inner shell and the outer shell, for example, the pressure of 17 bar and -115 ° C It is possible to store the pressurized liquefied natural gas having a temperature of, and may be designed to satisfy the above pressure and temperature conditions in a state in which the outer shell 52 and the heat insulation layer part 53 are assembled.

On the other hand, the inner shell 51 may be formed to have a small thickness (t1) compared to the thickness (t2) of the outer shell 52, thereby reducing the use of expensive metal having excellent low-temperature characteristics when manufacturing.

The heat insulation layer part 53 is installed in the space between the inner shell 51 and the outer shell 52, and consists of a heat insulating material which reduces heat transfer. In addition, the structure or material design may be made so that the same pressure as the pressure in the inner shell 51 is applied to the heat insulation layer part 53, where the same pressure as the pressure in the inner shell 51 means the same degree of rigidity. It does not mean to include a similar degree.

The inside of the heat insulating layer portion 53 and the inner shell 51 may be connected to each other by a connection passage 54 for pressure balance between the inside and the outside of the inner shell 51. This connection flow path 54 is the pressure balance in and out of the inner shell 51 (inside the outer shell 52), the outer shell 52 supports a significant portion of the pressure of the inner shell 51 The thickness can be reduced.

As shown in FIG. 12, the connection passage 54 may be formed at a side where the heat insulation layer part 53 is in contact with the connection part 55 provided at the entrance and exit 51a of the inner shell 51. Therefore, the pressure in the inner shell 51 moves toward the heat insulation layer part 53 through the connection flow passage 54 so that the pressure is balanced between the inside and the outside of the inner cell 51.

As shown in FIG. 13, an appropriate BOR (Boil Off Rate) is reduced while reducing heat transfer between an inner shell 51 made of a metal having excellent low temperature characteristics and an outer shell 52 made of a steel material having excellent strength. By installing a heat insulating layer 53 having a thickness for maintaining a) it is possible to store not only liquefied natural gas but also pressurized liquefied natural gas, due to the pressure balance between the inside and the outside of the inner shell 51 inner shell (51) It is possible to reduce the use of expensive metals having excellent low temperature properties by reducing the thickness t1 of. In addition, the occurrence of structural defects due to the internal pressure of the inner shell 51 can be prevented, and the storage container 50 excellent in durability can be provided.

On the other hand, the connection portion 55 is connected to be integrally formed in the inlet (51a) formed for the supply and discharge of the liquefied natural gas in the inner shell 51 is provided to protrude to the outside of the outer shell 52, such as an external member such as a valve May be connected.

As shown in FIG. 14, according to the storage container of the liquefied natural gas according to the second embodiment of the present invention, an outer insulation layer 56 may be provided on the outside of the outer shell 52 for thermal insulation. Here, the outer insulation layer 56 is attached to the outer shell 52 so as to surround the outer side of the outer shell 52, or to maintain the state surrounding the outer shell 52 by its shape formed or manufactured, and thus To prevent heat transfer from the outside. Therefore, it is possible to reduce BOG generated from liquefied natural gas or pressurized liquefied natural gas stored in a storage container in a high temperature environment such as the tropics.

As shown in FIG. 15, according to the storage container of the liquefied natural gas according to the third embodiment of the present invention, a heating member 57 may be installed outside the outer shell 52 for heating. In addition, the heating member 57 is a fruit circulation line for supplying heat to the outer shell 52 by the circulation supply of fruit, or a power source supplied from a battery or a capacitor or an external power supply unit attached to the storage container 50. It may be made of a heater that generates heat, it may be made of a plate-like heating element that can be bent or a heating wire wound along the outer surface of the outer shell 52 as in this embodiment.

Therefore, by making the liquefied natural gas or pressurized liquefied natural gas stored in the storage container in a low temperature environment such as the polar region from being affected by the external cold air, the outer shell 52 can be manufactured with a general steel sheet, thereby reducing the manufacturing cost. Can be.

16 is a cross-sectional view showing a storage container of liquefied natural gas according to a fourth embodiment of the present invention. As shown in FIG. 16, the storage container 60 for liquefied natural gas according to the fourth embodiment of the present invention surrounds the inner shell 61 and the outer shell 61 in which the liquefied natural gas is stored inside. Between the outer shell 62, a support 63 for supporting the inner shell 61 and the outer shell 62 and a heat insulating layer portion 64 for reducing heat transfer are provided. On the other hand, in order to supply and discharge the liquefied natural gas for the inner shell 61, the connection portion (not shown) is integrally connected to the entrance and exit of the inner shell 61 may protrude to the outside of the outer shell 62, such An external member such as a valve may be connected to the connection portion.

The inner shell 61 forms a space for storing the liquefied natural gas therein and has a low temperature characteristic such as aluminum, stainless steel, 5-9% nickel steel, etc. It may be made, as in the present embodiment may be made in the form of a tube, or may have a variety of shapes, including other polyhedra.

The outer shell 62 surrounds the outside of the inner shell 61 to form a space between the inner shell 61 and may be made of a steel material to withstand the internal pressure. By sharing the internal pressure to be applied to reduce the amount of material used in the inner shell 61 can reduce the production cost.

Since the inner shell 61 is equal to or close to the pressure of the inner shell and the heat insulating layer by the connection flow path, the pressure of the liquefied natural gas can be supported by the outer shell. Therefore, even if the inner shell 61 is manufactured to withstand temperatures of -120 to -95 ° C, the above-described pressure (13-25 bar) and temperature conditions by the inner shell and the outer shell, for example, the pressure of 17 bar and -115 ° C It is possible to store the pressurized liquefied natural gas having a temperature of, and may be designed to satisfy the above pressure and temperature conditions in an assembled state of the outer shell 62, the support 63, and the heat insulation layer 64.

The support 63 is installed in the space between the inner shell 61 and the outer shell 62 to support the inner shell 61 and the outer shell 62 to structurally form the inner shell 61 and the outer shell 62. Reinforcement, and may be made of metal (eg, low temperature steel) to withstand the low temperature of liquefied natural gas, and as shown in FIG. 17, a single along the side circumference of the inner shell 61 and the outer shell 62. Alternatively, as in the present embodiment, the inner shell 61 and the outer shell 62 may be installed in a plurality at intervals up and down.

As shown in FIG. 18, the support base 63 includes first and second flanges 63a and 63b supported on the outer surface of the inner shell 61 and the inner surface of the outer shell 62, and the first and second flanges 63a and 63b. It may include a first web (Webc) 63c provided between the second flange (63lang, 63b). Here, each of the first and second flanges 63a and 63b may be formed in a ring shape or may be formed of a curvature member in which a plurality of ring shapes are divided.

In addition, the support 63 may be fixedly supported by welding on the outer surface of the inner shell 61 and the inner surface of the outer shell 62 without using a separate member such as a flange. In this case, glass fibers may be inserted into the support to prevent heat from being transferred to the outside through the support.

The first web 63c may be formed of a plurality of gratings whose ends are fixed to the first and second flanges 63a and 63b, respectively. Here, the grating may be fixed so that a part is mainly subjected to a compressive force between the first and second flanges 63a and 62b, and the other may be fixed to form a truss structure, and the shape and the fixing position may be changed or adjusted. The same applies to the case where the web 63c is fixedly supported by welding to the inner and outer shells.

An insulation member 65 may be installed between the inner surface of the outer shell 62 and the second flange 63b to block heat transfer. Here, the heat insulating member 65 may be made of glass fiber, and prevents the temperature of the inner shell 61 from being transferred to the outer shell 62 by the support 63.

In addition, when the support 63 is fixed by welding, a heat insulating member such as glass fiber is disposed at the end of the support 63 in contact with the outer shell 62 and then fixed by welding, or a separate heat insulating member is provided. By placing between the outside of the support and the inside of the outer shell, it is possible to prevent the temperature of the inner shell 61 is transmitted to the outer shell 62 by the support 63.

The storage container 60 of the liquefied natural gas according to the present invention has a lower support 66 installed in a lower space between the inner shell 61 and the outer shell 62 to support the inner shell 61 and the outer shell 62. ) May be further included. Here, the lower support 66 is the third and fourth flanges supported on the outer surface of the inner shell 61 and the inner surface of the outer shell 62 and the second web provided between the third and fourth flanges, respectively. The second web may include a plurality of gratings having both ends fixed to the third and fourth flanges, respectively, and for these components, the support 63 may be different from the specific shape according to the installation position. The contrasting components are the same. In addition, a heat insulating member (not shown) may be installed between the inner surface of the outer shell 62 and the fourth flange to block thermal shear. Here, the heat insulating member may be made of glass fiber.

The heat insulation layer part 64 is installed in the space between the inner shell 61 and the outer shell 62, and is made of a heat insulating material to reduce heat transfer. In addition, the heat insulating layer portion 64 may be designed so that the same pressure as the pressure in the inner shell 61 is applied, where the same pressure as the pressure in the inner shell 61 does not mean exactly the same, In addition, the insulation layer 64 and the inside of the inner shell 61 are connected to each other as in the previous embodiment shown in FIG. 12 to balance pressure between the inside and outside of the inner shell 61. (54; shown in FIG. 12), and the connection flow path 54 has been described in detail in the previous embodiment, and thus description thereof will be omitted.

In addition, the heat insulating layer portion 64 may be made of a heat insulating material (eg, perlite) in the form of grains (eg, perlite) that may pass through the support 63, particularly the web 63 c of the grating structure. Therefore, when filling, the insulating layer 64 in the form of particles may be freely mixed and filled so that a gap does not occur between the inner shell 61 and the outer shell 62 so that the thermal insulation performance may be excellent.

In addition, since the support 63 and the lower support 66 of the grating support structure system is filled, the particle flow of the heat insulating layer 64 is freed, and thus, the heterogeneity of the heat insulating layer 64 may be prevented.

As shown in Fig. 19, the storage vessel 70 of the liquefied natural gas according to the fifth embodiment of the present invention may also be installed in the transverse direction, in which case the lower support 66 in the previous embodiment (Fig. 16). ) Can be omitted.

20 is a cross-sectional view showing a storage container of liquefied natural gas according to a sixth embodiment of the present invention.

As shown in FIG. 20, the storage container 80 for liquefied natural gas according to the sixth embodiment of the present invention surrounds the inner shell 81 and the outer shell 81 in which the liquefied natural gas is stored inside. A heat insulation layer 84 is provided between the outer shells 82 to reduce heat transfer, and the outer surface of the inner shell 81 and the inner surface of the outer shell 82 are connected by the metal core 83. On the other hand, in order to supply and discharge the liquefied natural gas for the inner shell 81, the connection portion (not shown) is integrally connected to the entrance and exit of the inner shell 81 may protrude to the outside of the outer shell 82, such An external member such as a valve may be connected to the connection portion.

The inner shell 81 forms a space for storing liquefied natural gas inside, and has a low temperature property such as aluminum, stainless steel, 5-9% nickel steel, etc. It may be made, as in the present embodiment may be made in the form of a tube, or may have a variety of shapes, including other polyhedra.

The outer shell 82 surrounds the outer side of the inner shell 81 to form a space between the inner shell 81 and may be made of a steel material to withstand the internal pressure. By sharing the applied internal pressure to reduce the material of the inner shell 81 can reduce the production cost.

Since the inner shell 81 is equal to or close to the pressure of the inner shell and the heat insulating layer by the connecting flow path, the pressure of the liquefied natural gas can be supported by the outer shell. Therefore, even if the inner shell 81 is manufactured to withstand temperatures of -120 to -95 ° C, the pressure (13-25 bar) and the temperature conditions described above by the inner shell and the outer shell, for example, the pressure of 17 bar and -115 ° C It is possible to store the pressurized liquefied natural gas having a temperature of, and may be designed to satisfy the above pressure and temperature conditions in an assembled state of the outer shell 82, the metal core 83, and the heat insulating layer 84. .

The metal core 83 is connected to the outer surface of the inner shell 81 and the inner surface of the outer shell 82 so that the inner shell 81 and the outer shell 82 are supported by each other, and the inner shell 81 and the outer shell are supported. It may be installed along the side circumference of the shell 82, as in the present embodiment may be installed in a plurality of spaced up and down at the side of the inner shell 81 and the outer shell 82. The metal padding 83 may be formed of a wire such as a steel wire. Here, the metal core 83 is connected to, for example, a plurality of rings provided on the outer surface of the inner shell 81 and the inner surface of the outer shell 82, or fastened or welded to the support points 83a provided in the plurality. In addition, the inner shell 81 and the outer shell 82 may be connected in various ways.

As shown in FIG. 21, the metal core 83 is connected to two support points 83a of the adjacent outer shell 82 while one support point 83a of the inner shell 81 is connected to the outer shell 82. One support point 83a may be repeatedly installed to be connected to two support points 83a of the adjacent inner shell 81, and may be connected to be arranged in a zigzag along the circumference between the inner shell 81 and the outer shell 82. And, as in (a) and (b), the number of connections to the number can vary.

The storage container 80 of liquefied natural gas according to the present invention has a lower support 86 installed in a lower space between the inner shell 81 and the outer shell 82 to support the inner shell 81 and the outer shell 82. ) May be further included. Here, the lower support 86 may include a flange which is respectively supported on the outer surface of the inner shell 81 and the inner surface of the outer shell 82, and a web provided between the flanges, both ends of the web on the flange It may be composed of a plurality of gratings each fixed, these components are the same as the lower support 66 of the storage container 60 of the liquefied natural gas according to the fourth embodiment will be omitted.

The heat insulation layer part 84 is installed in the space between the inner shell 81 and the outer shell 82, and consists of a heat insulating material which reduces heat transfer. In addition, the structure or material design may be made so that the same pressure as the pressure in the inner shell 81 is applied to the heat insulating layer portion 84, where the same pressure as the pressure in the inner shell 81 is the same in strict meaning. It also includes cases of minor differences. In addition, the heat insulating layer 84 and the inner shell 81 are connected to the connecting flow path 54 (shown in FIG. 12) as in the previous embodiment shown in FIG. 12 to balance the pressure between the inner shell 81 and the outer side. It can be connected to each other by, and since the connection flow path 54 has been described in detail in the previous embodiment will not be described.

The heat insulation layer part 84 may be made of a heat insulating material having a grain shape that may pass through the metal core 83. Therefore, when filling, the insulating layer 84 in the form of particles can be freely mixed and filled, so that a gap does not occur between the inner shell 81 and the outer shell 82, thereby preventing the heterogeneity of the insulating layer 84 from being excellent. Have insulation performance.

As shown in Figure 22, the storage vessel 90 of the liquefied natural gas according to the present invention may be installed in the transverse direction, in which case the lower support 86 (FIG. 20) in the previous embodiment may be omitted. have.

FIG. 23 is a block diagram showing a storage container of liquefied natural gas according to an eighth embodiment of the present invention.

As shown in FIG. 23, the storage container 510 of the liquefied natural gas according to the eighth embodiment of the present invention surrounds the inner shell 511 and the outer shell of the inner shell 511 in which the liquefied natural gas is stored. Including an outer shell 512, the inner space of the inner shell 511 and the space between the inner shell 511 and the outer shell 512 is connected to each other by the equalizing line 514. In addition, the insulating layer 513 may be installed between the inner shell 511 and the outer shell 512.

The inner shell 511 forms a space for storing the liquefied natural gas therein, and a metal having excellent low temperature characteristics such as aluminum, stainless steel, 5-9% nickel steel, etc. It may be made in the form of a tube, as in the present embodiment, or may have various shapes including other polyhedrons.

Since the inner shell 511 is equal to or close to the pressure of the inner shell and the heat insulating layer by the connection flow path, the pressure of the liquefied natural gas can be supported by the outer shell. Therefore, even when the inner shell 511 is manufactured to withstand temperatures of -120 to -95 ° C, the above-described pressure (13-25 bar) and temperature conditions, for example, a pressure of 17 bar and -115 ° C by the inner shell and the outer shell It is possible to store the pressurized liquefied natural gas having a temperature of, and may be designed to satisfy the above pressure and temperature conditions in an assembled state of the outer shell 512 and the insulating layer portion 513.

A first exhaust line 515 is connected to the upper portion of the inner space of the inner shell 511 and extends to the outside, and a first exhaust valve 515a is installed in the first exhaust line 515 to open and close the flow of gas. . Therefore, the first exhaust line 515 allows the gas to be discharged from the inner space of the inner shell 511 to the outside by opening the first exhaust valve 515a.

In addition, the first and second connection parts 516a and 516b are connected to the upper and lower ends of the inner space of the inner shell 511 to protrude outward through the outer shell 512. Therefore, the unloading line 8 connected to the second connecting portion 516b enables the liquefied natural gas to be loaded into the inner shell 511 through the loading line 7 connected to the first connecting portion 516a. Through the inner shell 511 to be able to unload the liquefied natural gas inside. Meanwhile, valves 7a and 8a may be installed in the docking line 7 and the unloading line 8, respectively.

The outer shell 512 surrounds the outside of the inner shell 511 to form a space between the inner shell 511 and is made of a steel material to withstand the internal pressure, and is applied to the inner shell 511. To reduce the manufacturing cost by reducing the material of the inner shell 511 by sharing the internal pressure.

On the other hand, the inner shell 511 may be formed to have a smaller thickness than the thickness of the outer shell 512, thereby reducing the use of expensive metal having excellent low-temperature characteristics when manufacturing the storage container 510.

The heat insulation layer part 513 is installed in the space between the inner shell 511 and the outer shell 512, and is made of a heat insulating material to reduce heat transfer. In addition, a structure or a material design may be made to apply a pressure equal to the pressure in the inner shell 511 to the heat insulation layer part 513.

The equalizing line 514 connects the inner space of the inner shell 511 and the inner space of the inner shell 511 and the outer space by connecting the space between the inner shell 511 and the outer shell 512 to each other. This minimizes the pressure difference between the inner pressure of the inner shell 511 and the inner shell 511 and the outer shell 512 so that these pressures can be balanced. Accordingly, the pressure difference between the inner and outer sides of the inner shell 511 is minimized, thereby reducing the pressure applied to the inner shell 511, thereby reducing the thickness of the inner shell 511, thereby reducing the thickness of the inner shell 511. It is possible to reduce the use of metal, to prevent structural defects caused by the internal pressure of the inner shell 511, and to provide a storage container 510 having excellent durability.

A support 517 may be installed in a space between the inner shell 511 and the outer shell 512 to support the inner shell 511 and the outer shell 512. The support 517 structurally reinforces the inner shell 511 and the outer shell 512, and may be made of a metal to withstand low temperature of liquefied natural gas, and the inner shell 511 and the outer shell 512 may be formed of a metal. Along the side circumference may be installed as a single, as in the present embodiment may be installed in a plurality of spaced apart up and down at the sides of the inner shell 511 and the outer shell 512.

In addition, a lower support 518 may be installed in a lower space between the inner shell 511 and the outer shell 512 to support the inner shell 511 and the outer shell 512.

The support 517 and the lower support 518, like the support 63 shown in FIG. 18, have flanges supported on the inner surfaces of the inner shell 511 and the outer shell 512, respectively, and webs provided between these flanges. It may include, the web may be made of a plurality of gratings, both ends of which are fixed to each of the flange, a heat insulating member such as glass fiber to block heat transfer between the outer shell 512 and the flange may be installed. In addition, the support 517 is connected to the inner surface of the inner shell 511 and the outer surface of the outer shell 512, similar to the metal core 83 shown in FIG. 20, the inner shell 511 and the outer shell 512. ) Can be supported by each other.

As shown in FIG. 24, according to the storage container of liquefied natural gas according to the ninth embodiment of the present invention, an opening / closing valve 514a for opening and closing a flow of a fluid, such as natural gas or boil-off gas, to the equalizing line 514. ) Can be installed. Therefore, in the case of changing the position or attitude of the storage container, the movement of the fluid through the equalizing line 514 can be blocked by the opening / closing valve 514a.

As shown in FIG. 25, according to the storage container of liquefied natural gas according to the tenth embodiment of the present invention, the second exhaust line 514c having the second exhaust valve 514b installed in the equalizing line 514 is provided. The gas inside the inner shell 511 may be discharged to the outside through the equalizing line 514 and the second exhaust line 514c by opening the second exhaust valve 514b. Therefore, it is possible to avoid a complicated process for connecting the exhaust line to the inner shell 511, to maintain structural stability and to easily install the exhaust line.

26 is a cross-sectional view showing a storage container of liquefied natural gas according to an eleventh embodiment of the present invention.

As shown in FIG. 26, the storage container 100 for liquefied natural gas according to the eleventh embodiment of the present invention includes an inner shell 110 and an inner shell 110 formed of a metal for enduring low temperature of the liquefied natural gas. Insulation layer portion 130 for reducing heat transfer is installed between the outer shell 120 surrounding the outside, and the connection portion 140 is provided on the inner shell 110 and the outer shell 120, the connection portion 140 A first flange 142 is provided at the end of the injection portion 141 extending outward from the inner shell 110 to be flanged in contact with the valve 4, and the injection portion 141 is provided from the outer shell 120. A second flange 144 is formed at the end of the extension 143 extending to surround the valve (4) for flange connection to the valve (4).

The inner shell 110 forms a space for storing the liquefied natural gas inside, and has a low temperature characteristic such as aluminum, stainless steel, 5-9% nickel steel, etc. It may be made in the form of a tube, as in the present embodiment, or may have various shapes including other polyhedrons.

The outer shell 120 surrounds the outer side of the inner shell 110 to form a space between the inner shell 110 and may be made of a steel material to withstand the internal pressure and applied to the inner shell 110. The paper to reduce the material of the inner shell 110 by sharing the internal pressure to reduce the manufacturing cost.

Since the inner shell 110 has a pressure equal to or close to that of the inner shell and the insulation layer due to the connection flow path, the pressure of the liquefied natural gas can be supported by the outer shell. Therefore, even if the inner shell 110 is manufactured to withstand temperatures of -120 to -95 ° C, the pressure (13 to 25bar) and temperature conditions described above, for example, the pressure of 17bar and -115 ° C by the inner shell and the outer shell. It is possible to store the pressurized liquefied natural gas having a temperature of, and may be designed to satisfy the above pressure and temperature conditions in an assembled state of the outer shell 120 and the heat insulating layer 130.

On the other hand, the inner shell 110 may be formed to have a smaller thickness than the thickness of the outer shell 120, thereby reducing the use of expensive metal having excellent low-temperature characteristics when manufacturing.

The heat insulating layer 130 is installed in the space between the inner shell 110 and the outer shell 120, and is made of a heat insulating material to reduce heat transfer. In addition, the structure or material design may be made so that the same pressure as the pressure in the inner shell 110 is applied to the heat insulating layer 130, where the same pressure as the pressure in the inner shell 110 is the same in the exact sense. But a bit more pressure is also applicable.

The inside of the heat insulating layer 130 and the inner shell 110 may be connected to each other by a connection flow path (not shown) for the pressure balance between the inner shell 110 and the outside. Here, the connection flow path may include various embodiments capable of providing a flow path such as a hole, a pipe, or the like, and may include, for example, a hole formed in the injection part 141 of the connection part 140. Therefore, the pressure in the inner shell 110 is moved to the heat insulation layer portion 130 side through the connection flow path so that the internal pressure of the inner cell 110 and the internal pressure of the heat insulation layer portion 130 are balanced.

The connection part 140 is connected to the flow path between the injection part 141 and the valve 4 by the first flange 142 is in direct contact with the valve 4 and flanged by the bolt 181 and the nut 182. Since the injection portion 141 and the first flange 142 directly contact the liquefied natural gas, the same material as that of the inner shell 110, for example, a metal having excellent low temperature characteristics, such as aluminum, stainless steel, 5-9% nickel steel, or the like. Can be done.

In addition, the connecting portion 140, as in the present embodiment, the extension portion 143 wraps the outside of the injection portion 141 at intervals, the second flange 144 is sandwiched between the first flange 142 valve 4 ) May be flanged to the bolt 181 and the nut 182, and the extension 143 and the second flange 144 may be made of steel.

As shown in FIG. 27, the connection part 150 is integrally formed with the injection part 151 by screwing the first flange 152 to the injection part 151.

As shown in FIG. 28, the connection part 160 may allow the first flange 162 to be fixed to the injection part 161 with a fastening member 163 such as a bolt or a screw. Here, the fastening member 163 may be fastened in a circumferential direction to the coupling portion 163a formed at the end of the injection portion 161 through the first flange 162.

In the case of using the bolt as the fastening member 163, as shown in Fig. 28 (a), the female thread is machined on the coupling part 163a and the first flange 162, and the first flange is a bolt with a separate male thread. 162 and the injection section 161a, where the head of the bolt with male thread can accommodate the head of the bolt in the first flange 162 to avoid interference with the surrounding members. The shape of the shape can be processed.

However, if the head of the bolt is configured to come out of the first flange as shown in Figure 28 (b) so as to accommodate the head of the bolt on the valve 4 side to avoid interference between the head of the bolt and the surrounding members The bolt head shape should be machined and fastened to the first flange.

As shown in FIG. 29, the connection portion 170 is formed by the bolt 181 and the nut 182 with the second flange 174 positioned at the edge of the first flange 172 and in contact with the valve 4. Flange can be connected. In this case, the first flanges 172 may be coupled to each other only by bolts 183 to the valve 4.

30 is an enlarged view illustrating main parts of a storage container of liquefied natural gas according to a twelfth embodiment of the present invention.

As shown in FIG. 30, the storage container 520 of the liquefied natural gas according to the twelfth embodiment of the present invention surrounds the inner shell 521 and the outer shell of the inner shell 521 in which the liquefied natural gas is stored. A buffer part 525 is provided to cushion the heat shrink between the inner shell 521 and the connection part 524 that includes an outer shell 522 and is connected to the outer injection part 9a and protrudes into the heat insulating layer part 523. Further, the heat insulation layer part 523 may be installed in the space between the inner shell 521 and the outer shell 522.

The inner shell 521 forms a space for storing the liquefied natural gas therein, and has a low temperature characteristic such as aluminum, stainless steel, 5 to 9% nickel steel, etc. It may be made in the form of a tube, as in the present embodiment, or may have various shapes including other polyhedrons.

The outer shell 522 surrounds the outer side of the inner shell 521 so as to form a space between the inner shell 521 and is made of a steel material to withstand the internal pressure, and is applied to the inner shell 521. By reducing the internal pressure of the paper to reduce the material of the inner shell 521 to reduce the manufacturing cost.

Since the inner shell 521 is equal to or close to the pressure of the inner shell and the heat insulating layer by the connection flow path, the pressure of the liquefied natural gas can be supported by the outer shell. Therefore, even if the inner shell 521 is manufactured to withstand temperatures of -120 to -95 ° C, the above-described pressure (13-25 bar) and temperature conditions by the inner shell and the outer shell, for example, the pressure of 17 bar and -115 ° C It is possible to store the pressurized liquefied natural gas having a temperature of, and may be designed to satisfy the above pressure and temperature conditions in a state in which the outer shell 522 and the heat insulation layer part 523 are assembled.

On the other hand, the inner shell 521 may be formed to have a smaller thickness than the thickness of the outer shell 522, thereby reducing the use of expensive metal having excellent low-temperature characteristics when manufacturing the storage container 520.

The heat insulation layer part 523 is installed in the space between the inner shell 521 and the outer shell 522, and is made of a heat insulating material to reduce heat transfer. In addition, a structure or a material design may be made to apply the same pressure as the pressure in the inner shell 521 to the heat insulation layer part 523.

The connection part 524 is provided to protrude from the inner shell 521, is connected to the injection hole 521a side formed to inject liquefied natural gas from the inner shell 521, protrudes outward, and liquefies to the inner shell 521. It may be connected to the external injection unit 9a for injecting natural gas, and may be connected to the inner shell 521 through the buffer unit 525. At this time, the outer shell 522 is provided with an extension portion 522a on one side to surround the connection portion 524, for example, the end of the extension portion 522a is connected to the external injection portion 9a together with the connection portion 524. Can be.

The buffer part 525 is provided to cushion the heat shrink between the inner shell 521 and the connection part 524 to cushion the heat shrinkage generated in the inner shell 521 to prevent concentration of the load in the connection part 524. do.

In addition, the shock absorbing portion 525 may be formed in the form of a pipe forming the joint 525b so that both ends are connected to the inlet 521a and the connecting portion 524 of the inner shell 521 by a flanged joint or the like as in the present embodiment. . In addition, the buffer part 525 may be formed to be integrated between the inner shell 521 and the connection part 524.

As shown in FIG. 31, the buffer part 525 may have a loop 525a. As in the present embodiment, the loop 525a may be formed in a single shape, and the planar shape may be polygonal, for example, quadrangular.

As shown in (a) of FIG. 32, the shock absorbing portion 526 is composed of a single loop 526a, the planar shape of which may be circular, as shown in (b) of FIG. 527 may have a coil shape including a plurality of loops 527a, and the coil may have a rhombic shape in which a width thereof decreases from the center portion to the both ends thereof. Accordingly, the impact due to heat shrinkage of the inner shell 521 by the loops 526a and 527a is alleviated.

33 is a block diagram showing an apparatus for producing liquefied natural gas according to the present invention.

In the apparatus 200 for producing liquefied natural gas according to the present invention, a heat exchanger 230 is installed in each of the first branch lines 221 branched from the supply line 220 of natural gas, respectively, and the heat exchanger 230. Cools the natural gas supplied through the first branch line 221 using the refrigerant supplied from the refrigerant supply unit 210 and removes the carbon dioxide condensed on each of the heat exchangers 230 by the regeneration unit 240. Regeneration fluid is supplied in place of natural gas.

Apparatus 200 for producing liquefied natural gas according to the present invention is not only liquefied natural gas, but also pressurized liquefied natural gas pressurized at a constant pressure, for example, pressurized liquefied natural cooled to -120 to -95 ° C at a pressure of 13 to 25 bar. It can also be used for the production of gases.

The refrigerant supply unit 210 supplies the refrigerant for heat exchange with natural gas to the heat exchanger 230 so that the natural gas is liquefied in the heat exchanger 230.

The heat exchanger 230 is installed in each of the first branch line 221 branched from the supply line 220 of the natural gas to a plurality of them are connected in parallel to each other, the refrigerant is supplied to the natural gas supplied from the supply line 220 Cooling by heat exchange with the refrigerant supplied from the supply unit 210, the total capacity exceeds the liquefied natural gas production can be made to maintain one or a plurality of atmospheric conditions during the production of the liquefied natural gas.

The number and capacity of the heat exchanger 230 may be determined in consideration of the liquefied natural gas production of the entire plant, for example, in the case of the heat exchanger 230 that can cover 20% of the total liquefied natural gas production A stand can be provided, five of them can be operated, and the rest can be kept in a standby state. This configuration allows the carbon dioxide to be shut down for the frozen heat exchanger and the standby heat exchanger can be operated while the frozen carbon dioxide is removed, thereby keeping the total yield of liquefied natural gas in the entire plant constant.

The regeneration unit 240 selectively supplies each of the heat exchangers 230 with a regeneration fluid for removing condensed carbon dioxide in place of natural gas. In addition, the regeneration unit 240 is a regeneration fluid supply unit 241 for supplying a regeneration fluid and a regeneration fluid connected to the front and rear ends of the heat exchanger 230 in each of the first branch lines 221 from the regeneration fluid supply unit 241. A first valve 243 installed at a front end and a rear end of a fluid line 242 and a portion where the regeneration fluid line 242 is connected at each of the first branch lines 221, and a heat exchanger at the regeneration fluid line 242. The second valve 244 may be installed at the front and rear ends of each of the groups 230.

Here, the regeneration fluid supply unit 241 may use, for example, high temperature air as the regeneration fluid, and supply the high temperature air to the heat exchanger 230 using pressure or pumping force to convert the condensed carbon dioxide into a liquid or gas state. It can be removed by changing the phase.

The apparatus 200 for producing liquefied natural gas according to the present invention includes a heat exchanger 230 for checking the freezing of carbon dioxide for each of the heat exchangers 230 and controlling supply of regeneration fluid to each of the heat exchangers 230. Receiving the detection signal output from each of the detection unit 250 and the detection unit 250, which is installed to confirm the freezing of carbon dioxide for each of the first and second valves (243, 244) and the regeneration fluid supply unit (241) The control unit 260 may further include a control unit.

The control unit 260 checks the heat exchanger 230 in which freezing of carbon dioxide is generated from the detection signal output from the detection unit 250, and in order to supply the regeneration fluid to the heat exchanger 230, first, the first valve ( Blocking the supply of natural gas to the heat exchanger 230 by blocking 243, the regeneration fluid is supplied to the heat exchanger 230 by driving the regeneration fluid supply unit 241 and opening of the second valve 244, Carbon dioxide frozen in the heat exchanger 230 by the regeneration fluid is liquefied or vaporized to be removed. On the other hand, the control unit 260 may count the regeneration fluid by the timer to supply the heat exchanger 230 until the set time is over.

The sensing unit 250 may be formed as a flow meter for measuring the flow rate of the liquefied natural gas that is installed at the rear end of the heat exchanger 230 in each of the first branch lines 221 as in this embodiment. Therefore, when the flow rate value measured by the detector 250, which is a flow meter, is lower than or equal to the set value, it may be determined that freezing of carbon dioxide occurs in the corresponding heat exchanger 230.

In addition to the flow meter, the detection unit 250 may be installed in each of the first branch lines 221, and may be configured as a carbon dioxide measuring device for measuring the content of carbon dioxide contained in the gas at the front and rear ends of the heat exchanger 230. When the difference in the amount of carbon dioxide contained in the gas measured at the front and rear of the unit 230 is greater than or equal to the set amount, it may be determined that freezing of the carbon dioxide occurs in the heat exchanger 230.

Apparatus 200 for producing liquefied natural gas according to the present invention is a refrigerant line 211 for supplying a refrigerant from the refrigerant supply unit 210 to the heat exchanger 230 in order to stop the operation of the heat exchanger 230 in which freezing of carbon dioxide has occurred. ) Further includes a third valve 270 installed at a front end and a rear end of each of the heat exchangers 230. Here, the third valve 270 may be controlled by the control unit 260, for example, the control unit 260 is the front end and the rear end of the heat exchanger 230, the carbon dioxide is frozen through the detection unit 250 By blocking the third valve 270 positioned in the to stop the operation of the heat exchanger 230 in which carbon dioxide is frozen.

34 and 35 are side and front views of a floating structure having a storage tank carrying device according to the present invention.

As shown in Figures 34 and 35, the floating structure 300 having the storage device carrying device according to the present invention is a storage device carrying device on the floating structure 320 is installed to float on the sea by buoyancy 310 is installed. Here, the floating structure 320 may be a structure made of a barge type, or a vessel capable of sailing using its own thrust.

In the transportation device 310 of the storage tank according to the present invention, the rail 312 is provided along the moving direction of the storage tank 330 on the mounting table 311a which is lifted by the lifting unit 311, and the storage tank ( The transport cart 313 on which the 330 is loaded is installed to be movable along the rail 312.

By doing so, it is possible to reduce the impact on the storage tank than to carry the storage tank by using a crane or the like. In addition, by connecting a plurality of storage tanks, a large amount of cargo can be transported over a long distance, and thus other transportation in terms of cost. More efficient than means. Also, this is not a way of lifting and moving storage tanks, so it will be more effective for the movement of relatively heavy storage tanks.

Although the storage device 310 of the storage tank according to the present invention has been shown to be installed in the floating structure 320 as in this embodiment, it is not limited thereto, and may be fixed to the ground or installed in various other transportation devices.

The storage tank 330 may store liquefied natural gas or liquefied natural gas pressurized at a constant pressure, and various cargoes may be stored. On the other hand, the pressurized liquefied natural gas may be a natural gas liquefied at a pressure of 13 ~ 25bar and a temperature of -120 ~ -95 ℃, for the storage of the pressurized liquefied natural gas storage tank 330 at low temperature and pressure It can be made of a material and a structure to sufficiently endure.

In addition, the storage tank 330 is manufactured in a dual structure to store the liquefied natural gas or the liquefied natural gas pressurized at a constant pressure, and as described above, the internal pressure of the dual structure and the pressure inside the storage tank 330 are balanced. It is also possible to have a connection channel between the dual structure of the storage tank and the interior of the storage tank to achieve.

As shown in FIG. 36, the elevating unit 311 elevates the mounting table 311a up and down. For example, the lifting section 311a may elevate the mounting table 311a from the floating structure 320 to the upper surface of the quay wall 5. have. Here, the mounting table 311a may be installed by moving downwards on the hinge coupling portion 311c of the lower end on one side or both sides to open the moving platform 311b to provide a movement path of the transport cart 313. .

The moving scaffold 311b serves to limit the movement of the conveyance trolley 313 when folded upward, and when the loading table 311a rises to the same height as the height of the quay wall 5 by the lifting section 311. The transport cart 313 serves to safely move to the land by helping the connection between the quay wall 5 and the loading table 311a. In addition, the movable footrest 311b may be provided with an auxiliary rail 311d connected to the rail 312 on a surface facing upward when unfolded downward.

In addition, the lifting unit 311 may be used in various structures and actuators for the lifting of the mounting table 311a, for example, a plurality of coupling slidingly coupled to the upper and lower to the lower portion of the mounting table 311a By connecting to the lower portion of the member or the mounting table 311a to each other by the link member can be installed so that the mounting table 311 is movable up and down by a plurality of link members, such as stretched up and down in the rotational direction, for a linear motion The mounting table 311a may be raised and lowered by using an actuator such as a motor that provides a driving force or a cylinder operated by hydraulic pressure.

The rail 312 is installed along the moving direction of the storage tank 330 on the mounting table 311a, and is formed in a pair, and has the same width as the rail (not shown) of the train located on the inner wall 5. It can be arranged side by side to have. Therefore, when the conveyance trolley 313 raised by the elevating part 311 to the upper surface of the quay wall 5 moves along the rail 312 and moves to the rail on the quay wall 5, it is remoted by a land transportation device such as a train. It is possible to move.

The transport cart 313 is provided with a plurality of wheels 313a movable along the rails 312 at the lower part, and a storage tank 330 is loaded at the upper part, and one or both sides for connection of other transport carts 313. The connection portion may be provided. In addition, the transport cart 313 is equipped with a storage tank 330 may be provided with a tank guard 313b of steel material to protect the storage tank 330 from corrosion and external impact on the upper surface.

The feed cart 313 may be moved along the rail 312 by driving the winch, for example, by being connected to the winch through a cable, but not limited thereto, and conveying a rotational force to some or all of the wheels 313a. The driving unit (not shown) may travel along the rail 312 by magnetic force.

37 is a block diagram showing a high pressure maintaining system of the pressurized liquefied natural gas storage container according to the present invention. As shown in Figure 37, the high-pressure holding system 400 of the pressurized liquefied natural gas storage container according to the present invention is connected to the storage tank 6 of the consumer from the storage vessel 411 to enable the unloading of the pressurized liquefied natural gas Including the unloading line 410, the supply of a portion of the pressurized liquefied natural gas to be unloaded through the unloading line 410 to the storage container 411, for this purpose, the pressure supplement line 420 and the evaporator 430 ) May be further included.

The unloading line 410 is connected to the storage tank 6 of the consumer from the storage container 411 to enable the unloading of the pressurized liquefied natural gas, and pressurized liquefied natural only by the pressure of the pressurized liquefied natural gas stored in the storage container 411. It is possible to allow the gas to be unloaded into the storage tank 6. It is installed so that the loading line 410 extends from the upper portion to the lower portion of the storage tank 6 so that the pressurized liquefied natural gas can be unloaded to the storage tank 6 only by the pressure of the pressurized liquefied natural gas stored in the storage container 411. In addition, it is possible to minimize the generation of boil-off gas.

If the unloading line 411 is connected to the lower part of the storage tank 6 to further reduce the amount of boil-off gas generated at the time of unloading, the pressurized liquefied natural gas is loaded from the lower part of the storage tank, thereby reducing the amount of vaporized gas. However, since only the pressure of the pressurized liquefied natural gas stored in the storage container 411 may be insufficient to reliably unload the pressurized liquefied natural gas to the storage tank 6, a pump must be additionally installed in the unloading line.

Pressure supplement line 420 is branched from the unloading line 410 is connected to the storage container 411, the evaporator 430 is installed. In addition, the pressure filling line 420 may be connected to the upper portion of the storage container 411, so that the natural gas supplied to the storage container 411 through the pressure filling line 420 is pressurized in the storage container 411. The pressure reduction of the storage container 411 is reduced by minimizing liquefaction by contact with natural gas.

The evaporator 430 vaporizes the pressurized liquefied natural gas supplied through the pressure supplement line 420 to be supplied to the storage container 411. Therefore, the natural gas vaporized by the evaporator 430 is supplied to the storage container 411 through the pressure supplement line 420 to increase the pressure in the storage container 411 which is reduced during the initial unloading of the pressurized liquefied natural gas. Therefore, the pressure in the storage container 411 is maintained above the bubble point pressure of the liquefied natural gas.

The high pressure maintaining system 400 of the pressurized liquefied natural gas storage container according to the present invention may further include an evaporation gas line 440 and a compressor 450 to recover the boil-off gas generated in the storage tank of the consumption place as the liquefied natural gas. Can be.

Here, the boil-off gas line 440 is installed to supply the boil-off gas generated from the storage tank 6 to the storage container 411, and is connected to the lower portion of the storage container 411 to minimize the temperature change to the Increase recovery.

In addition, the compressor 450 is installed in the boil-off gas line 440 and compresses the boil-off gas supplied along the boil-off gas line 440 to be stored in the storage container 411. Therefore, while unloading the pressurized liquefied natural gas, the evaporated gas generated in the storage tank 6 is pressurized through the compressor 450 through the evaporation gas line 440 and then injected into the lower portion of the storage container 411 to condense. As a result, the transportation efficiency of the pressurized liquefied natural gas can be improved.

In addition, according to the high pressure maintaining system 400 of the pressurized liquefied natural gas storage container according to the present invention, since the evaporator 430 and the compressor 450 can be complemented with each other, the amount of boil-off gas generated in the storage tank 6 is increased. If not enough to maintain the pressure of the storage container 411, the load of the evaporator 430 increases, and if the evaporation gas is sufficient, the load of the evaporator 430 is reduced.

38 is a block diagram showing a separate heat exchanger liquefaction apparatus according to a thirteenth embodiment of the present invention.

As illustrated in FIG. 38, the heat exchanger separate type natural gas liquefaction apparatus 610 according to the thirteenth embodiment of the present invention is liquefied by heat exchange with a refrigerant by a liquefaction heat exchanger 620 made of stainless steel. The refrigerant is cooled by the refrigerant heat exchangers 631 and 632 made of aluminum to be supplied to the liquefaction heat exchanger 620.

The liquefaction heat exchanger 620 receives the natural gas through the liquefaction line 623 to liquefy by heat exchange with the refrigerant, and for this purpose, the liquefaction line 623 is connected to the first flow path 621 and the refrigerant circulation. The line 638 is connected to the second flow path 622 to allow the natural gas and the refrigerant passing through the first and second flow paths 621 and 622 to exchange heat with each other, and the entire portion may be made of stainless steel, but the present invention is not limited thereto. Instead, the liquefied natural gas such as the first flow path 621 may be partially made of stainless steel for parts or parts that need to be in contact with or have to withstand cryogenic temperatures. Here, the liquefaction line 623 is provided with an on-off valve 624 at the rear end of the first flow path (621).

The refrigerant heat exchangers 631 and 632 may be formed of a plurality of, for example, the first and second refrigerant heat exchangers 631 and 632 as in the present embodiment, but are not limited thereto and may be formed in a single unit, and the whole portion may be made of aluminum. In this case, the contact of the refrigerant and, consequently, the part or part requiring heat transfer may be partially made of aluminum. In addition, the refrigerant heat exchangers 631 and 632 may be included in the refrigerant cooling unit 630.

The refrigerant cooling unit 630 cools and supplies the refrigerant to the liquefaction heat exchanger 620 by the first and second refrigerant heat exchangers 631 and 632. For this purpose, the refrigerant cooling unit 630 discharges the liquefied heat exchanger 620. The refrigerant is compressed and cooled by a compressor 633 and an after-cooler 634, and the refrigerant passing through the after-cooler 634 is separated by the separator 635 into a gaseous refrigerant and a liquid refrigerant, The refrigerant is supplied to the first flow path 631a of the first refrigerant heat exchanger 631 and the first flow path 632a of the second refrigerant heat exchanger 632 by the gas phase line 638a, and the liquid refrigerant is supplied in the liquid phase. A low pressure is inflated by a first JT (Joule-Thomson) valve 636a along a connecting line 638c via a second flow path 631b of the first refrigerant heat exchanger 631 by a line 638b. 1 is supplied to the compressor 633 via the third flow path 631c of the heat exchanger 631 for the refrigerant to repeat the compression and subsequent processes. .

In addition, the refrigerant cooling unit 630 expands the high-pressure refrigerant passing through the first flow path 632a of the second refrigerant heat exchanger 632 to a low pressure by the second JT valve 636b to liquefy the heat exchanger ( The second flow path 632b of the second refrigerant heat exchanger 632 and the first refrigerant are expanded to a low pressure by the third JT valve 636c through the refrigerant supply line 637 and to be supplied to the 620. The compressor 633 is supplied to the compressor 633 via the third flow path 631c of the heat exchanger 631.

The aftercooler 634 removes the heat of compression of the refrigerant compressed by the compressor 633 and liquefies a part of the refrigerant. In addition, the first refrigerant heat exchanger 631 is configured to exchange the high temperature refrigerant before expansion supplied through the first and second flow passages 631a and 631b with the low temperature refrigerant after expansion supplied with the third flow passage 631c. Cool. The second refrigerant heat exchanger 632 cools the high temperature refrigerant before expansion supplied through the first flow passage 632a by heat exchange with the low temperature refrigerant after expansion supplied to the second flow passage 632b.

In addition, the liquefied heat exchanger 620 cools and liquefies natural gas by supplying the low-temperature refrigerant expanded through the first and second heat exchangers 631 and 632 and the second J-T valve 636b.

39 is a block diagram showing a separate heat exchanger liquefaction apparatus according to a fourteenth embodiment of the present invention.

As shown in FIG. 39, the heat exchanger separated type natural gas liquefaction apparatus 640 according to the fourteenth embodiment of the present invention is similar to the heat exchanger separated type natural gas liquefaction apparatus 610 according to the thirteenth embodiment. The liquefied heat exchanger 650 made of stainless steel and the liquefied heat exchanger 650 are liquefied by heat exchange with the refrigerant, and the refrigerant heat exchanger 661 is made of aluminum. It includes a refrigerant cooling unit 660 for cooling and supplying, the same configuration or parts as the heat exchanger separate type natural gas liquefaction apparatus 610 according to the thirteenth embodiment will be omitted, and the differences will be described.

The refrigerant cooling unit 660 compresses and cools the refrigerant discharged from the liquefaction heat exchanger 650 by the compressor 663 and the aftercooler 664 to the first flow path 661a of the refrigerant heat exchanger 661. And expand the refrigerant passing through the first flow path 661a of the refrigerant heat exchanger 661 by the expander 665 and supply the liquid refrigerant to the liquid heat exchanger 650 according to the operation of the flow distribution valve 666. The compressor 633 is supplied to the compressor 663 via the second flow path 661b of the refrigerant heat exchanger 661. Here, the flow distribution valve 666 may be made of a three-way valve as in this embodiment, alternatively may be made of a plurality of bidirectional valves.

The refrigerant heat exchanger 661 allows the high temperature refrigerant before expansion supplied through the first flow path 661a to be cooled by heat exchange with the low temperature refrigerant after expansion supplied through the second flow path 661b. In addition, the low temperature refrigerant is distributed to the refrigerant heat exchanger 661 and the liquefaction heat exchanger 650 according to the operation of the flow rate distribution valve 666, and the liquefied heat exchanger 650 is a refrigerant heat exchanger 661. And the low temperature refrigerant through the expander 665 to liquefy the natural gas.

40 and 41 are a front and side cross-sectional view showing a liquefied natural gas storage container carrier ship according to the present invention.

40 and 41, the liquefied natural gas storage container carrier 700 according to the present invention is a vessel for transporting a storage container in which the liquefied natural gas is stored, the cargo hold 720 provided in the hull 710 A plurality of first and second upper supports 730 and 740 for partitioning the upper portion of the cargo hold 720 into the plurality of openings 721 by being installed in a plurality of width and length directions at an upper portion thereof, and inserted into each opening 721. The storage container 791 is supported by the first and second upper supports 730 and 740.

On the other hand, the storage container 791 stores not only general liquefied natural gas but also liquefied natural gas pressurized at a constant pressure, for example, pressurized liquefied natural gas having a pressure of 13 to 25 bar and a temperature of -120 to -95 ° C. For this purpose, a double structure or a heat insulating member may be installed for this purpose, may be formed in a tube form or a cylinder form, and may have various other forms.

The cargo hold 720 may be provided so that the upper portion is opened to the hull 710, in which case the hull 710 may be utilized in the hull of the container ship. Therefore, the time required for manufacturing the LNG storage container carrier 700 can be reduced in cost.

As shown in FIG. 42, the first and second upper supports 730 and 740 are installed in the width direction and the length direction in the upper portion of the cargo hold 720 so that the upper portion of the cargo hold 720 can be opened to the plurality of openings 721. In each case, the storage container 791 is vertically inserted into and supported by the opening 721. That is, the first upper support 730 is installed in the width direction of the hull 710 on the upper portion of the cargo hold 720, a plurality of spaced apart along the longitudinal direction of the hull 710. In addition, the second upper support 740 is installed in the longitudinal direction of the hull 710 on the upper portion of the cargo hold 720, a plurality of spaced apart along the width direction of the hull 710. Accordingly, the first and second upper supports 730 and 740 are formed so that a plurality of openings 721 are formed in the transverse direction and the vertical direction on the upper portion of the cargo hold 720, and fixed by welding to the upper end of the cargo hold 720, It may be fixed by a fastening member such as a bolt.

In addition, a plurality of support blocks 760 for supporting the side of the storage container 791 may be installed on some or all of the inner surfaces of the first and second upper supports 730 and 740 and the cargo hold 720. The support block 760 may be provided to support the front, rear, left, and right sides of the storage container 791, respectively, and has a curvature corresponding to the curvature of the outer surface of the storage container 791 so as to stably support the storage container 791. Surface 761 may be formed.

The lower support 750 is installed at the lower portion of the cargo hold 720 and supports the lower portion of the storage container 791 inserted into the opening 721. The lower support 750 is installed at the bottom surface of the cargo hold 720 vertically upwardly. And, the reinforcing member 751 for maintaining the gap between each may be further installed. On the other hand, the lower support 750 and the reinforcing member 751 may be formed in one pair for each storage container 791, a plurality of storage containers 791 by being installed in a plurality of longitudinal and horizontal directions on the bottom surface of the cargo hold 720. ) To support the lower part.

The LNG carrier container ship 700 according to the present invention may use a Stanchion, a lashing bridge, etc. in the case of the container ship as it is, in order to support the storage container 791. The second upper supporters 730 and 740 may be fixedly supported on the stanza and the lashing bridge.

Due to this, the conventional container ship can be modified to enable the transport of the storage container 791 with only a few changes, and the container loading portion on the deck 711 to transport the container box 792 together with the storage container 791. There may be additional 770.

43 is a block diagram showing a carbon dioxide solidification removal system according to the present invention.

As shown in FIG. 43, the carbon dioxide solidification removal system 810 according to the present invention includes an expansion valve 812 for reducing the high pressure natural gas to a low pressure and a rear end of the expansion valve 812. And a solidification carbon dioxide filter 813 for filtering the frozen and solidified carbon dioxide present in the interior thereof, and a heating unit 816 for vaporizing the solidified carbon dioxide of the expansion valve 812 and the solidification carbon dioxide filter 813. Carbon dioxide solidified from the natural gas liquefied by the filter 813 is filtered, and heat is supplied from the heating unit 816 while the supply of natural gas to the expansion valve 812 and the solidified carbon dioxide filter 813 is stopped. It can be supplied to regenerate and remove solidified carbon dioxide.

The expansion valve 812 is installed in the supply line 811 to which the high pressure natural gas is supplied, and liquefies the high pressure natural gas supplied through the supply line 811 to a low pressure.

The solidified carbon dioxide filter 813 is installed at the rear end of the expansion valve 812 in the supply line 811 and filters the carbon dioxide solidified by freezing from the liquefied natural gas supplied from the expansion valve 812. A filter member for filtering is installed inside.

In addition, the expansion valve 812 and the solidified carbon dioxide filter 813 open and close the supply of the high pressure natural gas and the discharge of the low pressure liquefied natural gas by the first and second open / close valves 814 and 815. The open / close valves 814 and 815 are installed at the front end of the expansion valve 812 and the rear end of the solidified carbon dioxide filter 813 in the supply line 811 to open and close the flow of natural gas, respectively. Here, the first on-off valve 814 opens and closes the high pressure natural gas supply to the expansion valve 812, and the second on-off valve 815 opens and closes the discharge of the low pressure liquefied natural gas discharged from the solidified carbon dioxide filter 813. .

The heating unit 816 provides heat to vaporize the solidified carbon dioxide of the expansion valve 812 and the solidified carbon dioxide filter 813, for example, the fruit for heat exchange with the expansion valve 812 and the solidified carbon dioxide filter 813. Heat exchanger 816b installed in the heat supply line 816a to which the gas is circulated, and fourth and fifth open / close valves 816c installed at the front and rear ends of the regeneration heat exchanger 816b in the heat line 816a, respectively. 816d).

A third opening / closing valve 817 is installed in the discharge line 817a through which carbon dioxide is discharged to discharge carbon dioxide regenerated by the heating unit 816 to the outside.

The third open / close valve 817 discharges the carbon dioxide regenerated by the heating unit 816 to the discharge line 817a branching from the supply line 811 between the first open / close valve 814 and the expansion valve 812. It is installed to open and close.

In addition, the carbon dioxide solidification removal system 810 according to the present invention includes a plurality of first to third open / close valves 814, 815, 817 and a heating unit 816 such that some of the carbon dioxide is regenerated while some of the carbon dioxide is filtered. ) Can be controlled, and in the present embodiment, it consists of two, each of which performs alternating filtering and regeneration of carbon dioxide, the operation for this will be described with reference to the accompanying drawings.

As shown in FIG. 44, the carbon dioxide solidification removal system 810 according to the present invention will be described based on any one of the above-mentioned methods. First, through the supply line 811 by opening the first and second on-off valves 814 and 815. When the high pressure natural gas is supplied to the expansion valve 812 and the low pressure is expanded, the natural gas is cooled and the low pressure liquefied natural gas is supplied to the solidified carbon dioxide filter 813, and the solidified carbon dioxide contained in the liquefied natural gas by cooling is Filtered by a carbon dioxide filter 813. When the solidified carbon dioxide is continuously accumulated in the solidified carbon dioxide filter 813, the supply of the high pressure natural gas through the supply line 811 is stopped by closing the first and second open / close valves 814 and 815, and then the fourth and the second By opening and closing the five open / close valves 816c and 816d, the fruit is circulated to the regeneration heat exchanger 816b to supply heat to the expansion valve 812 and the solidified carbon dioxide filter 813 to regenerate the solidified carbon dioxide.

The regenerated carbon dioxide is removed by being discharged to the outside along the discharge line 817a by opening the third open / close valve 817.

In addition, when the carbon dioxide solidification removal system 810 according to the present invention is composed of a plurality of, for example, two, the first to fifth open / close valves 814, 815, 817, 816c, and 816d to perform carbon dioxide filtering solidified from natural gas. Is controlled, and the other (II) has the opposite operation, so that regeneration through the vaporization of the solidified carbon dioxide is performed.

As described above, the carbon dioxide solidification removal system 810 according to the present invention applies a low temperature method of freezing and separating carbon dioxide from the carbon dioxide removal method, thereby enabling the combination with the natural gas liquefaction process. In this case, the elimination of pretreatment carbon dioxide is not necessary, and thus a reduction in equipment occurs. In addition, when liquefied natural gas fed at a high pressure and the carbon dioxide is solidified during expansion and decompression at low pressure by the expansion valve 812, the solidified carbon dioxide is filtered with a solidifying carbon dioxide filter 813, which is a mechanical filter, and solidified When carbon dioxide is continuously accumulated in the solidified carbon dioxide filter 813, a plurality of solidified carbon dioxide filters 813 may be alternately used while simultaneously regenerating carbon dioxide.

45 is a cross-sectional view showing a connection structure of a liquefied natural gas storage container according to the present invention.

As shown in FIG. 45, the connection structure 820 of the LNG storage container according to the present invention includes an inner shell 831 and an external injection portion 840 of the LNG storage container 830 having a dual structure. As a structure for connecting, the inner shell 831 and the outer injection portion 840 is slidingly coupled, and may include a sliding coupling portion 821 for this purpose.

The sliding coupling portion 821 is provided at the connection portion between the inner shell 831 and the outer injection portion 840, and is thermally contracted or thermally expanded to cushion the thermal contraction or thermal expansion of the inner shell 831 or the outer shell 832. A connection portion of the inner shell 831 and the outer injection portion 840 may be provided to be slidable along the direction in which the displacement occurs.

On the other hand, the storage container 830, for example, liquefied natural gas is stored inside the inner shell 831, the outer shell 832 wraps the outside of the inner shell 831, the inner shell 831 and the outer shell ( An insulation layer portion 833 may be installed in the space between the 832 to reduce the temperature influence.

Here, the inner shell 831 may be made of a metal having excellent low temperature characteristics such as aluminum, stainless steel, 5-9% nickel steel, etc., which can withstand the low temperature of a general liquefied natural gas.

As in the previous embodiments, the storage container 830 may be made of a steel material for the outer shell 832 to withstand the internal pressure, and the inside of the inner shell 831 and the insulating layer part 833 are located. It may have a structure for applying the same pressure to the space, the pressure of the inside of the inner shell and the heat insulating layer portion can be the same or approximated by the connection flow path connecting the inner shell and the heat insulating layer portion, for example.

As a result, the pressure of the pressurized liquefied natural gas inside the inner shell is supported by the outer shell, so that the pressure described above by the inner shell and the outer shell even if the inner shell is manufactured to withstand temperatures of -120 to -95 ° C. 25 bar) and temperature conditions, for example pressurized liquefied natural gas having a pressure of 17 bar and a temperature of -115 ℃ is possible.

In addition, the storage container 830 may be designed to satisfy the above pressure and temperature conditions in a state where the outer shell and the heat insulating layer are assembled.

The sliding coupling portion 821 is a coupling portion 822 extending outward from the injection hole 831a formed for injection and discharge of liquefied natural gas into the inner shell 831 and a coupling portion protruding from the external injection portion 840 ( 823 may be made by slidingly coupled to each other by the fitting method.

As shown in FIG. 46, the connection part 822 and the coupling part 823 are formed in a circular tube, and any one of them may be inserted into the other and slidably coupled thereto, but is not limited thereto. Sliding coupling can be achieved by forming cross-sectional shapes corresponding to each other.

Connection structure 820 of the liquefied natural gas storage container according to the present invention may further include an extension portion 824 extending to surround the sliding coupling portion 821 from the outer shell 832. Therefore, the sliding coupling part 821 is exposed to the outside by the extension part 824, thereby preventing it from being affected by the external environment. In addition, the extension part 824 may be flange-coupled to the external injection part 840 by forming a flange at an end thereof, thereby allowing the storage container 830 to be stably coupled to the external injection part 840.

On the other hand, the coupling portion 823 provided in the external injection portion 840 may be formed to be integral with the external injection portion 840, as in the present embodiment, on the other hand, is made of a separate member from the external injection portion 840 It may be fixed to the extension 824, it may be coupled to the outer injection portion 840 by a flange coupling or a variety of ways.

As shown in Figure 47, the connection structure 820 of the liquefied natural gas storage container according to the present invention even if the load is concentrated on the connection portion between the inner shell 831 and the outer injection portion 840 by thermal contraction or thermal expansion The connection part 822 and the coupling part 823 can be slidably moved to each other to buffer thermal contraction or thermal expansion, thereby preventing the load from being concentrated on the inner shell 831 and the external injection part 840, thereby thermal contraction or thermal expansion. To prevent damage.

In addition, since the natural gas in the storage container 830 may move to the heat insulation layer portion 833 through a gap (tolerance) of the sliding coupling portion 821, the pressure of the heat insulation layer portion 833 and the pressure of the inner shell 831 are the same. It can also be approximated, which can also have the effect of replacing an equalizing line for maintaining the equivalent pressure of the inner layer and the inner layer as shown in FIGS. 23 to 25.

FIG. 48 is a view schematically showing a storage container of liquefied natural gas according to the present invention, FIG. 49 is a view schematically showing the structure of a storage container inner shell of liquefied natural gas according to the present invention, and FIG. 52 is a view showing the various forms of the structure of the inner shell of the liquefied natural gas storage container according to the invention, Figure 51 is a view showing the various forms of the structure of the inner shell of the storage container of the liquefied natural gas according to the present invention, Figure 52 Is a view schematically showing the structure of the inner shell of the storage container of liquefied natural gas according to the present invention, Figure 53 is a view schematically showing a storage container of the liquefied natural gas according to the present invention.

48 to 52, the storage container 900 of liquefied natural gas according to an embodiment of the present invention includes an inner shell 910, an outer shell 920, a support 930, and an insulating layer part 940. .

The storage container 900 of the present invention has an inner shell 910 and an outer shell 920 between an inner shell 910 in which liquefied natural gas is stored and an outer shell 920 surrounding the outer side of the inner shell 910. The support 930 to support the and the heat insulation layer portion 940 to reduce heat transfer is installed.

On the other hand, in order to supply and discharge the liquefied natural gas for the inner shell 910, the connection portion (not shown) is integrally connected to the entrance and exit of the inner shell 910 may protrude to the outside of the outer shell 920, such An external member such as a valve may be connected to the connection portion.

Inner shell 910, as shown in FIG. It may have a cylindrical (or tubular) shape with a corrugation structure 950, but may have various shapes including other polyhedrons.

The corrugation structure 950 formed in the inner shell 910 may have various bent portions 952 according to the cross-sectional shape of the corrugation, and may have one or more corrugations 951 having various bent portions 952.

One or more pleats 951 may determine the bend angle 953, pleat depth 954, pleat distance 955 to have the same shape throughout one inner shell 910 (FIG. 50A, 50A) b), (c)), the bending angle 953, the wrinkle depth 954, the wrinkle distance 955 may be determined such that some of them have different shapes or all of them have different shapes.

Various curved portions 952 may have various shapes such as an angled corner curved portion 9521, a rounded corner curved portion 9522, and a wavy curved portion 9523.

In the embodiment of FIG. 50A, an inner shell 910 is illustrated in which four angled corner curved portions 9521 are formed in one corrugation 951, and a bending angle 953 of the angled corner curved portion 9521 is illustrated. If you configure a variety of will be able to have a more diverse shape of wrinkles.

50 (b) and 50 (c), the inner shell 910 is formed so that one or more wrinkles 951 are different from each other in the wrinkle depth 954 and the wrinkle distance 955. The corner portion was rounded so as not to have an angled edge to have a rounded corner bent portion 9522.

In each of FIGS. 51A and 51B, the inner shell 910 is formed such that one or more wrinkles 951 are formed to have different wrinkle depths 954 and wrinkle distances 955. 951 shows an inner shell 910 having a wavy bend 9523 with wavy bends formed therein.

In addition, as shown in (a) and (b) of FIG. 52, the bent portions 9521 and 9522 having angled or rounded corners and the wavy portions 9523 may be formed in one corrugation. .

In FIGS. 48 and 49, the corrugation structure 950 is formed on the side surface of the outer surface of the inner shell 910, but the corrugation structure 950 is necessary if necessary for the upper cover 960 or the lower cover 970 as well as the side surface. Will be able to form.

The inner shell 910 forms a space for storing the liquefied natural gas therein, and has a low temperature characteristic such as aluminum, stainless steel, 5 to 9% nickel steel, etc., which can withstand the low temperature of the liquefied natural gas. It can be made of an excellent metal.

The outer shell 920 wraps the outside of the inner shell 910 to form a space between the inner shell 910 and may be made of a steel material to withstand the internal pressure, and the inner shell 910 By sharing the applied internal pressure, the amount of material used in the inner shell 910 may be reduced, thereby reducing manufacturing costs.

The heat insulation layer part 940 is installed in the space between the inner shell 910 and the outer shell 920, and is made of a heat insulating material to reduce heat transfer.

The heat insulating layer 940 may be designed to apply the same pressure as the pressure in the inner shell 910, where the same pressure as the pressure in the inner shell 910 does not mean exactly the same, but a similar degree It is also meant to include.

Insulating layer portion 940 and the inner shell 910 inside may be connected to each other by a connecting flow path 54 (shown in FIG. 12) as in the previous embodiment for pressure balance between the inner shell 910 inside and the outside, Since the connection flow path 54 has been described in detail in the previous embodiment, the description thereof will be omitted.

Since the inner shell 910 is equal to or close to the pressure of the inner shell and the heat insulating layer by the connection passage 54, the pressure of the liquefied natural gas can be supported by the outer shell. Thus, even though the inner shell 910 is manufactured to withstand temperatures of -120 to -95 ° C, the pressure (13-25 bar) and temperature conditions described above may be influenced by the inner shell and the outer shell, for example, a pressure of 17 bar and -115 ° C. It is possible to store the pressurized liquefied natural gas having a temperature of, and may be designed to satisfy the above pressure and temperature conditions in a state where the outer shell 920, the support 930, and the heat insulation layer part 940 are assembled.

Since the support 930 may be installed to have the same manner and function as described in the above-described other embodiments, a detailed description thereof will be omitted. It can be installed by adding a lower support 931 to the space.

As illustrated in FIG. 53, the storage container 900 of the liquefied natural gas according to the present invention may be installed in the transverse direction, in which case the lower support 931 may be omitted.

48 to 52 is a method of manufacturing a storage container 900 of liquefied natural gas of one embodiment of the present invention. The inner shell 910 having a corrugated structure is disposed inside the storage container, and the outer shell 920 is disposed outside the storage container, and the support 930 supporting the inner shell 910 and the outer shell 920. ) Is installed in the space between the inner shell 910 and the outer shell 920, the heat insulating layer portion 940 to reduce heat transfer is installed in the space between the inner shell 910 and the outer shell 920.

At this time, the corrugated structure of the inner shell 910 can be produced by connecting a plurality of the curved surface made by using a roller (roller) by welding.

Rollers for making corrugated structures include not only ordinary rollers but also all kinds of rollers capable of making corrugated structures (such as corrugated rollers) such as corrugated rollers. After the corrugation is made, the joints are welded to produce a storage container 900 for liquefied natural gas.

Since the configuration and function of each part constituting the storage container manufactured in this manner is the same as described above, a detailed description thereof will be omitted.

54 is a view schematically showing a structure of a liquefied natural gas storage container according to the present invention, and FIGS. 55 to 57 are views schematically showing a protruding support of a liquefied natural gas storage container according to the present invention. ) Is a plan view, (b) is a side view, and Figure 58 is a view schematically showing the structure of a liquefied natural gas storage container according to the present invention.

The liquefied natural gas storage container according to the present invention is connected to the hinge and the support points of the inner shell and the outer shell instead of the volume-type supporting method, which is a conventional method of supporting the inner shell.

The liquefied natural gas storage container 1000 according to one embodiment of the present invention illustrated in FIGS. 54 to 58 includes an inner shell 1010, an outer shell 1020, a hinge support 1030, and an insulating layer part 1050.

The inner shell 1010 stores the liquefied natural gas inside, the outer shell 1020 surrounds the outside of the inner shell 1010 to form a space between the inner shell 1010, the heat insulation layer portion 1050 is Installed in the space between the inner shell 1010 and the outer shell 1020 to reduce heat transfer.

On the other hand, in order to supply and discharge the liquefied natural gas for the inner shell 1010, the connection portion (not shown) is integrally connected to the entrance of the inner shell 1010 may protrude to the outside of the outer shell 1020, such An external member such as a valve may be connected to the connection portion.

The hinge support 1030 may be installed in a plurality of spaces between the inner shell 1010 and the outer shell 1020 so as to hingely support the inner shell 1010 and the outer shell 1020, and the longitudinal direction of the storage container 1000. And it can be installed at intervals in any one or more of the circumferential direction, Figure 54 shows a plurality of installed in the longitudinal direction.

The hinge support 1030 is installed in a space between the inner shell 1010 and the outer shell 1020 to support the inner shell 1010 and the outer shell 1020 to structurally form the inner shell 1010 and the outer shell 1020. Reinforced to, and may be made of a metal (for example, low-temperature steel) to withstand the low temperature of the liquefied natural gas, a plurality of spaced along the side circumference of the inner shell 1010 and the outer shell 1020, or It may be provided in plurality at intervals up and down, and may be installed in a plurality at intervals up and down the sides.

The hinge support 1030 may be fixedly supported by welding to an outer surface of the inner shell 1010 and an inner surface of the outer shell 1020. In this case, in order to prevent heat from being transferred to the outside through the support, a heat insulating material such as glass fiber is inserted into the support, or a separate heat insulating member is disposed between the outside of the support and the inside of the outer shell, so that the temperature of the inner shell 1010 is increased. It may be prevented from being delivered to the outer shell 1020 by the hinge support (1030).

The hinge support 1030 may include one or more hinge rods 1033, one or more hinge lugs 1032, and hinge pins 1031.

The hinge rod 1033 connects the inner shell 1010 and the outer shell 1020, and hinge pins 1031 are inserted at both ends, and the hinge lugs 1032 are hinges inserted at both ends of the hinge rod 1033. The inner shell 1010 and the outer shell 1020 are respectively installed to support the pin 1031, so that the inner shell 1010 and the outer shell 1020 can be hinged to each other by the hinge pins 1031.

Since the inner shell 1010 and the outer shell 1031 are connected by a hinge structure, the hinge structure can absorb heat shrinkage or thermal expansion of the inner shell 1010 due to temperature change.

Therefore, the hinge structure can absorb the stress caused by the heat change that can occur in the support, and can also absorb the concentration of the load, thereby preventing the damage of the support due to the concentration of stress structural structural stability and Durability can be increased.

The hinge pin insertion hole 1034 formed in the hinge lug 1032 may form a space in the horizontal direction so that the inserted hinge pin 1031 may move in the horizontal direction.

This is to relieve stress that may occur in the hinge support 1030 by the horizontal space accommodates and supports the movement of the inner shell 1010 caused by thermal contraction or thermal expansion.

As shown in FIGS. 55 to 57, the hinge support 1030 may be configured such that the hinge lugs 1032 evenly support the vertical loads of the inner shell 1010 and the outer shell 1020. The horizontal projection surface may be formed such that the left and right sides are symmetrical with respect to the radial center line 1035 of the storage container 1000.

This is to prevent this because when the unbalanced vertical load is applied to the hinge lug 1032, unnecessary rotational force is applied to increase the possibility of damage to the hinge lug 1032.

As illustrated in FIG. 55, the hinge rod 1033 is installed to be inclined with respect to the horizontal direction, and the hinge rod 1033 is installed to be inclined. As shown in FIG. 54, the heat shrink of the inner shell 1010? The hinge rod 1033 can rotate to absorb thermal expansion.

If two hinge rods 1033 are installed, as shown in FIG. 56, one may have an inclination of the upper right side, and the other may have an inclination of the lower right side, as shown in FIG. 57. It may also have a portion that is bent in opposite directions at opposite positions.

This allows the horizontal projection surface of the hinge support 1030 to be symmetrical with respect to the radial center line 1035 to distribute even vertical loads to the hinge lugs 1032 and thus absorb heat shrinkage or thermal expansion of the inner shell 1010 well. To do so.

The inner shell 1010 forms a space for storing the liquefied natural gas therein, and has a low temperature characteristic such as aluminum, stainless steel, 5 to 9% nickel steel, etc. It may be made, as in the present embodiment may be made in the form of a tube, or may have a variety of shapes, including other polyhedra.

The outer shell 1020 wraps the outside of the inner shell 1010 to form a space between the inner shell 1010 and may be made of a steel material to withstand the internal pressure, and the inner shell 1010 By sharing the applied internal pressure, the use of the material of the inner shell 1010 may be reduced, thereby reducing the manufacturing cost.

The heat insulation layer part 1050 is installed in the space between the inner shell 1010 and the outer shell 1020, and is made of a heat insulating material to reduce heat transfer.

The heat insulating layer portion 1050 may be designed to apply the same pressure as the pressure in the inner shell 1010, where the same pressure as the pressure in the inner shell 1010 does not mean exactly the same, but a similar degree. It is also meant to include.

Inside the insulation layer 1050 and the inner shell 1010 may be connected to each other by a connecting flow path 54 (shown in FIG. 12), as in the previous embodiment, for the pressure balance between the inner shell 1010 and the outer shell, Since this connection flow path has been described in detail in the previous embodiment, the description thereof will be omitted.

Since the inner shell 1010 is equal to or close to the pressure of the inner shell and the heat insulating layer by the connection flow path, the pressure of the liquefied natural gas can be supported by the outer shell. Therefore, even if the inner shell 1010 is manufactured to withstand temperatures of -120 to -95 ° C, the pressure (13-25 bar) and temperature conditions described above, for example, the pressure of 17 bar and -115 ° C by the inner shell and the outer shell. It is possible to store the pressurized liquefied natural gas having a temperature of, and may be designed to satisfy the above pressure and temperature conditions in an assembled state of the outer shell 1020, the protruding support 1030, and the insulating layer part 1050. .

The storage container 1000 of liquefied natural gas according to the present invention has a lower support 1040 installed in a lower space between the inner shell 1010 and the outer shell 1020 to support the inner shell 1010 and the outer shell 1020. It may further include, and as described in the hinge support (1030) to insert the heat insulating material such as glass fiber in the support to prevent heat transfer to the outside through the support, or to separate the heat insulating member and the outer shell of the support. Placed between the inner side, it is possible to prevent the temperature of the inner shell 1010 is transmitted to the outer shell 1020 by the lower support 1040.

As shown in Figure 58, the liquefied natural gas storage container 1000 according to the present invention may be installed in the transverse direction, the lower support 1040 in addition to the protruding support 1030 as in the case of installing in the longitudinal direction You can install additional.

FIG. 59 is a view schematically showing a structure of a liquefied natural gas storage container according to the present invention, FIG. 60 is an enlarged view of a portion A of FIG. 59, and (a) is a view when the inner shell is expanded, (b) is a view when the inner shell is shrunk, Figure 61 is a view schematically showing the structure of the liquefied natural gas storage container according to the present invention, (a) is a view provided with two lower supports, (b) is a view showing a cross-sectional view, Figure 62 is a view schematically showing the structure of a liquefied natural gas storage container according to the present invention.

The liquefied natural gas storage container according to the present invention allows the outer shell to support the inner shell in a sliding manner by a protrusion member separated to have an inclined cross section instead of a volume type supporting method which is a conventional method for supporting the inner shell.

The liquefied natural gas storage container 1100 according to an embodiment of the present invention illustrated in FIGS. 59 to 62 includes an inner shell 1110, an outer shell 1120, a protruding support 1130, and an insulating layer part 1150.

The inner shell 1110 stores the liquefied natural gas inside, and the outer shell 1120 surrounds the outer side of the inner shell 1110 to form a space between the inner shell 1110 and the heat insulation layer part 1150. Installed in the space between the inner shell 1110 and the outer shell 1120 to reduce heat transfer.

Meanwhile, in order to supply and discharge the liquefied natural gas to the inner shell 1110, a connection part (not shown) may be integrally connected to the entrance and exit of the inner shell 1110 to protrude to the outside of the outer shell 1120. An external member such as a valve may be connected to the connection portion.

Protruding support 1130 is installed in the space between the inner shell 1110 and the outer shell 1120 so as to support the inner shell 1110 and the outer shell 1120 by connecting with a separate projecting member having an inclined cross section, As illustrated in FIG. 61, a plurality of storage containers 1100 may be provided in a plurality of intervals in at least one of a longitudinal direction and a circumferential direction, and FIG. 59 illustrates a plurality of longitudinally installed ones in FIG. 61. b) shows a plurality provided in the circumferential direction.

Since the inner shell 1110 and the outer shell 1120 are connected to the protrusion support 1130 having an inclined cross section facing each other, the protrusion support 1130 is inclined to prevent thermal contraction or thermal expansion of the inner shell 1110 due to temperature change. It can be absorbed while sliding along.

Therefore, the protruding support 1130 can absorb the stress that may occur in the support due to thermal contraction or thermal expansion of the inner shell 1110, and also absorbs the concentrated load, thereby preventing damage to the support due to the concentration of stress. It is possible to increase the structural stability and durability of the storage container (1000).

As shown in FIG. 61, the protrusion support 1130 may be installed at regular intervals in the circumferential direction. In this case, since the load or the stress distribution is evenly applied to the protrusion support 1130, the durability of the protrusion support 1130 may be improved. It can be improved.

The protrusion support 1130 is installed in a space between the inner shell 1110 and the outer shell 1120 to support the inner shell 1110 and the outer shell 1120 to structurally form the inner shell 1110 and the outer shell 1120. Reinforced to, and may be made of a metal (for example, low temperature steel) to withstand the low temperature of the liquefied natural gas, a plurality of spaced along the side circumference of the inner shell 1110 and the outer shell 1120, or It may be provided in plurality at intervals up and down, and may be installed in a plurality at intervals up and down the sides.

The protrusion support 1130 may be fixedly supported by welding to an outer surface of the inner shell 1110 and an inner surface of the outer shell 1120. In this case, in order to prevent heat from being transferred to the outside through the support, a heat insulating material such as glass fiber is inserted into the support, or a separate heat insulating member is disposed between the outside of the support and the inside of the outer shell, so that the temperature of the inner shell 1110 is increased. It may be prevented from being transmitted to the outer shell 1120 by the protrusion support 1130.

The protrusion support 1130 may include a lower support block 1131, an upper support block 1132, and a sliding member 133.

The lower support block 1131 has an inclined upper cross section, and the upper support block 1132 has an inclined lower cross section, and the lower cross section of the upper support block 1132 moves on the upper cross section of the lower support block 1131. To help.

Since the outer shell 1120 should be able to support thermal expansion and thermal contraction of the inner shell 1110 according to the temperature change of the inner shell 1110, the lower support block 1131 located at the bottom of the inclined support block is the outer shell. An upper support block 1132 attached to the upper portion 1120 and positioned at an upper portion of the upper support block 1132 is attached to the inner shell 1110 to be a lower end surface of the upper support block 1132 attached to the inner shell 1110. The upper shell of the lower support block 1131 attached to the outer shell 1120 can be supported while moving.

At this time, a plurality of grooves may be formed in the upper end surface of the lower support block 1131 or the lower end surface of the upper support block 1132 so that the upper support block 1132 can move the lower support block 1131 smoothly.

As a result, when the upper support block 1132 moves on the lower support block 1131, the frictional force decreases due to the reduction of the friction surface, and stress concentration of the storage container structure due to the friction force, abrasion, etc. between the support blocks 1131 and 1132. Can be reduced.

In addition, the sliding member 1133 may be further added to any one of an upper end surface of the lower support block 1131 or a lower end surface of the upper support block 1132.

The sliding member 1133 also allows the upper support block 1132 to smoothly move on the lower support block 1131 to prevent frictional forces or stress concentration, thereby stress concentration of the storage container structure or between the support blocks 1131 and 1132. The durability of the storage container can be increased by reducing the wear on the container.

As the sliding member 1133, a spring or a roller may be used, and the like, and the present disclosure is not limited thereto and may include any device that allows the upper support block to smoothly move on the lower support block with a small friction force.

As shown in (a) of FIG. 60, when the spring is used as the sliding member 1133, the upper support block 1132 of the lower support block 1131 may be formed when the elastic force of the spring is thermally expanded by the inner shell 1110. It can be easily moved to the upper side to further relieve stress concentration due to thermal expansion.

 60 (b) shows a state in which the inner shell 1110 is lowered to the lower portion of the lower support block 1131 by thermal contraction.

The inner shell 1110 forms a space for storing the liquefied natural gas therein, and has a low temperature characteristic such as aluminum, stainless steel, 5 to 9% nickel steel, etc. It may be made, as in the present embodiment may be made in the form of a tube, or may have a variety of shapes, including other polyhedra.

The outer shell 1120 surrounds the outer side of the inner shell 1110 to form a space between the inner shell 1110 and may be made of a steel material to withstand the internal pressure, and may be formed in the inner shell 1110. By sharing the internal pressure applied to reduce the amount of the material of the inner shell 1110 to reduce the production cost.

The heat insulation layer part 1150 is installed in a space between the inner shell 1110 and the outer shell 1120 and is made of a heat insulating material to reduce heat transfer.

The heat insulating layer 1150 may be designed such that a pressure equal to the pressure in the inner shell 1110 is applied, where the same pressure as the pressure in the inner shell 1110 does not mean exactly the same, but a similar degree. It is also meant to include.

Inside the heat insulation layer portion 1150 and the inner shell 1110 may be connected to each other by a connecting flow path 54 (shown in FIG. 12) as in the previous embodiment for the pressure balance between the inner shell 1110 and the outside, Since this connection flow path has been described in detail in the previous embodiment, the description thereof will be omitted.

Since the inner shell 1110 is equal to or close to the pressure of the inner shell and the heat insulating layer by the connection flow path, the pressure of the liquefied natural gas can be supported by the outer shell. Thus, even though the inner shell 1110 is manufactured to withstand temperatures of -120 to -95 ° C, the above-described pressure (13-25 bar) and temperature conditions by the inner shell and the outer shell, for example, the pressure of 17 bar and -115 ° C It is possible to store the pressurized liquefied natural gas having a temperature of, and may be designed to satisfy the above pressure and temperature conditions in an assembled state of the outer shell 1120, the protrusion support 1130, and the heat insulation layer part 1150. .

The storage container 1100 of liquefied natural gas according to the present invention includes a lower support 1140 installed in a lower space between the inner shell 1110 and the outer shell 1120 to support the inner shell 1110 and the outer shell 1120. It may further include, and as described in the hinge support (1130) to insert the heat insulating material such as glass fiber in the support to prevent heat transfer to the outside through the support, or to separate the heat insulating member and the outer shell of the support. By placing between the inner side, it is possible to prevent the temperature of the inner shell 1110 is transmitted to the outer shell 1120 by the lower support 1140.

In addition, as shown in (a) of FIG. 61, the lower support 1140 may be provided in plural, and in this case, since the load received by the lower support 1140 is distributed, the durability of the lower support 1140 may be improved. You can do it.

As illustrated in FIG. 62, the liquefied natural gas storage container 1100 according to the present invention may be installed in the transverse direction, and the lower support 1140 in addition to the protruding support 1130 as in the case of installing in the longitudinal direction. You can install additional.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

1: natural gas field 2: ship
3: consumer 3a: consumer
4: valve 5: quay
6: storage tank 7: loading line
7a: valve 8: unloading line
8a: valve 9a: external inlet
10: pressurized liquefied natural gas production system
11: dehydration equipment 12: liquefaction equipment
13: carbon dioxide removal system 14: storage facility
21: storage container 21a: nozzle
22: container assembly 22a: integrated nozzle
23: regasification system 30: storage tank of liquefied natural gas
31: body 31a: spacer
31b: support 32: storage container
33: Unloading line 33a, 33b: Unloading valve
34: boil off gas line 34a, 34b: boil off gas valve
35 pressure sensing unit 36 control unit
36a: operation unit 37: display unit
38: heating part 38a: heat exchanger
38b: electric heater 39: calorific value control unit
41: bypass line 41a: bypass valve
42: temperature detection unit 50: storage container
51: inner shell 51a: doorway
52 outer shell 53 heat insulation layer
54: connection path 55: connection part
56: outer insulation layer 57: heating member
60,70: storage container 61: inner shell
62: outer shell 63: support
63a: first flange 63b: second flange
63c: first web 64: heat insulation layer portion
65: heat insulation member 66: lower support
80,90: storage container 81: inner shell
82 outer shell 83 metal core
83a: support point 84: heat insulation layer
86: lower support 100: storage container
95: inner shell 120: outer shell
130: heat insulating layer 140,150,160,170: connection
141,151,161: injection part 142,152,162,172: first flange
143: extension 144,174: second flange
163: fastening member 163a: coupling portion
181,183: bolt 182: nut
200: production device of pressurized liquefied natural gas 210: refrigerant supply unit
211: refrigerant line 220: supply line
221: first branch line 230: heat exchanger
240: regeneration unit 241: regeneration fluid supply unit
242: regeneration fluid line 243: first valve
244: second valve 250: detector
260 control unit 270 third valve
300: floating structure having a storage tank transport device
310: conveying device of the storage tank 311: lifting unit
311a: Loading Table 311b: Moving Scaffold
311c: hinge coupling portion 311d: auxiliary rail
312: rail 313: feed cart
313a: Wheel 313b: Tank Guard
320: floating structure 330: storage tank
400: high pressure maintenance system of pressurized liquefied natural gas storage container
410: unloading line 411: storage container
420: pressure fill line 430: evaporator
440: boil-off gas line 450: compressor
510: storage container 511: inner shell
512: outer shell 513: heat insulation layer
514: equalizing line 514a: on-off valve
514b: second exhaust valve 514c: second exhaust line
515: first exhaust line 515a: first exhaust valve
516a: first connection part 516b: second connection part
517: support 518: lower support
520: storage container 521: inner shell
521a injection hole 522 outer shell
522a: extension portion 523: heat insulation layer portion
524: connection 525,526,527: buffer
525a, 526a, 527a: loop 525b: joint
610,640: Separator for natural gas liquefied heat exchanger
620,650: liquefied heat exchanger 621: first flow path
622: 2nd Euro 623: liquefaction line
624: opening / closing valve 630, 660: refrigerant cooling section
631,632,661: Refrigerant heat exchanger 631a, 632a, 661a: First flow path
631b, 632b, 661b: 2nd Euro 631c: 3rd Euro
633,663 Compressor 634,664 After Cooler
635: separator 636a: first JT valve
636b: Second JT Valve 636c: Third JT Valve
637: refrigerant supply line 638: refrigerant circulation line
638a: weather line 638b: liquid line
638c: connection line 665: inflator
666 flow distribution valve
700: LNG storage vessel carrier
710: hull 711: deck
720: cargo hold 721: opening
730: first upper support 740: second upper support
750: lower support 751: reinforcing member
760: support block 761: support surface
770: loading container 791: storage container
792: container box
810: carbon dioxide solidification removal system 811: supply line
812: Expansion Valve 813: Solidified Carbon Dioxide Filter
814: first on-off valve 815: second on-off valve
816: heating part 816a: heating line
816b: regenerative heat exchanger 816c: fourth open and close valve
816d: fifth open / close valve 817: third open / close valve
817a: discharge line
820: connection structure of liquefied natural gas storage container
821: sliding engagement portion 822: connection portion
823 coupling portion 824 extension portion
830 liquefied natural gas storage container 831: inner shell
831a: inlet 832: outer shell
833: insulating layer 840: external injection portion
900: storage container for liquefied natural gas 910: inner shell
920: outer shell 930: support
931: lower support 940: insulation layer
950: wrinkle structure 951: wrinkle
952: bend portion 9521: angled corner bend
9522: rounded corner bend 9523: wavy bend
953: bending angle 954: depth of wrinkles
955: wrinkle distance 960: top cover
970: lower cover
1000: storage container for liquefied natural gas 1010: inner shell
1020: outer shell 1030: hinge support
1031: Hinge pin 1032: Hinge lug
1033: hinge rod 1034: hinge pin insertion hole
1035: radial center line 1040: lower support
1050: heat insulation layer
1100: liquefied natural gas storage container 1110: inner shell
1120: outer shell 1130: protruding support
1131: lower support block 1132: upper support block
1133: sliding member 1140: lower support
1150: heat insulation layer

Claims (10)

In the structure of the liquefied natural gas storage container,
An inner shell 1110 in which the liquefied natural gas is stored inside;
An outer shell 1120 surrounding an outer side of the inner shell 1110 to form a space between the inner shell 1110;
An insulating layer part 1150 installed in a space between the inner shell 1110 and the outer shell 1120 and reducing heat transfer; And
And a protruding support 1130 formed to protrude into the space on the outside of the inner shell 1110 and the inside of the outer shell 1120.
Protruding ends of the protruding support 1130 have inclined cross sections facing each other;
Structure of liquefied natural gas storage container, characterized in that. The method according to claim 1,
The protrusion support 1130 is provided with a plurality of intervals in any one or more of the longitudinal direction and the circumferential direction of the storage container 1100;
Structure of liquefied natural gas storage container, characterized in that. The method according to claim 2,
The protrusion support 1130,
A lower support block 1131 having an inclined upper section; And
Including; an upper support block 1132 having an inclined lower end surface;
A lower end surface of the upper support block 1132 moving on an upper end surface of the lower support block 1131;
Structure of liquefied natural gas storage container, characterized in that. The method according to claim 3,
A plurality of grooves formed on the upper or lower end surface;
Structure of liquefied natural gas storage container, characterized in that. The method according to claim 3,
The protrusion support 1130,
A sliding member 1133 formed on a lower end surface of the upper support block 1132 or an upper end surface of the lower support block 1131;
Structure of the liquefied natural gas storage container further comprises a. The method according to claim 5,
The sliding member 1133 may include a spring or a roller;
Structure of a liquefied natural gas storage container comprising a. The method according to any one of claims 1 to 6,
The inner shell 1110 is made of a metal that withstands low temperature of liquefied natural gas, the outer shell 1120 is made of a steel (steel) material to withstand the internal pressure;
Structure of liquefied natural gas storage container, characterized in that. The method of claim 7,
The inner shell 1110 withstands the temperature of -120 ~ -95 ℃, the outer shell 1120 to withstand the pressure of 13 ~ 25bar;
Structure of liquefied natural gas storage container, characterized in that. The method according to claim 8,
A space between the inner shell 1110 and the outer shell 1120 of the storage container such that the pressure between the inner shell 1110 and the outer shell 1120 of the storage container and the pressure of the inner shell 1110 are balanced. A connection flow path installed between the inner shells 1110;
Structure of a liquefied natural gas storage container comprising a. In the structure of the liquefied natural gas storage container,
A heat insulation layer portion is installed between the inner shell in which the liquefied natural gas is stored and the outer shell surrounding the outer side of the inner shell, and an inner side of the inner shell and the inner side of the outer shell have an inclined cross section. Supported by separate projecting members;
Structure of liquefied natural gas storage container, characterized in that.

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