JP2007131686A - Method for delivering gas hydrate pellet and device for the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a single device capable of being used as both a depressurizing device and cooling device for depressurizing and cooling gas hydrate pellets formed under the atmosphere of a high pressure gas. <P>SOLUTION: This method for delivering the gas hydrate pellets (p) from the inside of the high pressure gas (g) for forming the gas hydrate, to a storage vessel under normal pressure comprises (a) a process of injecting coolant liquid (m) into containers (3a to 3c) for delivering the gas hydrate pellets, (b) a process of putting the gas hydrate pellets (p) into the containers (3a to 3c) injected with the coolant liquid (m) so as to cool the gas hydrate pellets (p), (c) a process of depressurizing the inside of the containers (3a to 3c) by extracting the coolant liquid (m) in the containers (3a to 3c), and (d) a process of delivering the cooled hydrate pellets (p) under normal pressure from the containers (3a to 3c) reduced with the pressure. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a gas hydrate pellet dispensing method and apparatus for dispensing gas hydrate pellets from a high pressure gas hydrate product gas into a storage tank under normal pressure.

  Conventionally, as a gas hydrate manufacturing system, there is a system as shown in FIG. This gas hydrate manufacturing system includes a first generator 101, a dehydrator 102, a second generator 103, a granulator 104, a depressurizer 105, a cooler 106, a storage tank 107, and a gas compressor 108. .

  A high-pressure (for example, 54 ata (5.29 MPa)) raw material gas (natural gas) g and a normal temperature (for example, 5 ° C.) raw material water w are supplied to the first generator 101, and a stirring / bubbling method, etc. The gas hydrate is generated by bringing the raw material gas g and the raw material water w into gas-liquid contact by any of the above methods. The heat of reaction generated during the generation of the gas hydrate is removed using the cold heat of LNG.

  The gas hydrate generated in the first generator 101 is supplied to the dehydrator 102 in the state of slurry s (for example, the gas hydrate content is about 20%) and dehydrated (for example, the water content is about 50%). ). The water w ′ dehydrated by the dehydrator 102 is mixed into the original raw material water w.

  The gas hydrate h dehydrated by the dehydrator 102 is supplied to the second generator 103 and further dehydrated (for example, a moisture content of 10% or less). The raw material gas g supplied from the first generator 101 is used for dehydration in the second generator 103. That is, the moisture content of the gas hydrate is substantially reduced by the reaction between the raw material gas g and the water w accompanying the gas hydrate to newly generate gas hydrate.

  The gas hydrate h dehydrated in the second generator 103 is formed into gas hydrate pellets p having an arbitrary shape and size by a granulator (pelletizer) 104. Since this gas hydrate pellet p is molded in an atmosphere of a high-pressure (54 ata (about 5.29 MPa)) source gas (gas hydrate product gas) g, the decompression device 105 is suitable for storage and transportation. The pressure is reduced to a pressure, and then cooled to about −20 ° C., which is said to be able to exert a self-preserving effect by the cooler 106. The gas hydrate pellets p cooled by the cooler 106 are stored in a storage tank 107 under normal pressure.

  The purge gas g ′ decompressed by the depressurization device 105 is increased to the same pressure as the raw material gas g by the gas compressor 108 and returned to the upstream side of the first generator 101.

Such a gas hydrate manufacturing system is known in addition to the above (for example, Patent Document 1).
JP 2003-105362 A (pages 11-12, FIG. 11)

  However, when the purge gas g ′ decompressed by the depressurization device 105 is reduced to the upstream side of the first generator 101, the purge gas g ′ is converted into the gas pressure of the raw material gas g using the gas compressor 108 (for example, 54ata ( Since it is necessary to increase the pressure to about 5.29 MPa)), there is a problem that not only the high-pressure gas compressor 108 is required, but also power consumption for operating the gas compressor 108 is increased.

  In addition, since the conventional gas hydrate production system needs to provide the decompression device 105 and the cooler 106 separately, the equipment cost increases correspondingly, the process becomes longer, and the maintenance management becomes troublesome. There is a problem of becoming.

  The present invention has been made to solve such problems, and its purpose is to suppress the generation of purge gas when storing gas hydrate pellets molded in an atmosphere of high-pressure gas under normal pressure. It is another object of the present invention to provide a gas hydrate pellet dispensing method and apparatus capable of dispensing gas hydrate.

  Another object of the present invention is to provide a gas hydrate pellet in which a decompressor and a cooler for decompressing and cooling gas hydrate pellets molded in an atmosphere of high-pressure gas are combined in one device. It is to provide a payout method and apparatus.

In order to solve the above problems, the present invention is configured as follows.
The method for dispensing gas hydrate pellets according to the invention of claim 1 is a method for dispensing gas hydrate pellets in which gas hydrate pellets are dispensed from a high-pressure gas hydrate product gas into a storage tank under normal pressure. (A) A step of injecting a refrigerant liquid into a container for discharging gas hydrate pellets, (b) a step of cooling the gas hydrate pellets by introducing the gas hydrate pellets into the container into which the refrigerant liquid has been injected. (C) A method for discharging the gas hydrate pellets, comprising: a step of extracting the refrigerant liquid from the container and depressurizing the inside of the container; and (d) a step of discharging the gas hydrate pellets cooled from the decompressed container to normal pressure. It is.

  The method for dispensing gas hydrate pellets according to the invention of claim 2 has at least three containers for delivering the gas hydrate pellets, and the steps (a) to (d) are carried out with respect to each other between the containers. The method for discharging gas hydrate pellets according to claim 1, wherein the discharging is carried out sequentially.

  According to a third aspect of the present invention, there is provided a gas hydrate pellet dispensing method, wherein the refrigerant gas generated when the refrigerant liquid is extracted from the gas hydrate pellet dispensing container is liquefied using the cold heat of liquefied natural gas. The method for dispensing gas hydrate pellets according to claim 1.

  A gas hydrate pellet dispensing apparatus according to a fourth aspect of the present invention is the gas hydrate pellet dispensing apparatus for dispensing gas hydrate pellets from a high-pressure gas hydrate product gas to a storage tank under normal pressure. A container for discharging the basic gas hydrate pellet, a refrigerant supply valve for sequentially distributing the refrigerant liquid to the container, and a gas hydrate pellet input for charging the gas hydrate pellet into the container into which the refrigerant liquid has been injected A valve, a pressure reducing valve for discharging the refrigerant liquid from the container charged with the gas hydrate pellets, a gas hydrate pellet discharging valve for discharging the gas hydrate pellets of the decompressed container under normal pressure, and the pressure reducing valve A gas hide comprising a refrigerant reliquefier that reliquefies the refrigerant gas vaporized when decompressed It is a dispenser of Toperetto.

  As described above, when the gas hydrate pellets are discharged from the high-pressure gas hydrate product gas into the storage tank under normal pressure, the invention according to claim 1 is (a) for discharging gas hydrate pellets. Injecting a refrigerant liquid into the container; (b) introducing the gas hydrate pellets into the container into which the refrigerant liquid has been injected to cool the gas hydrate pellets; and (c) supplying the refrigerant liquid in the container. A step of extracting and depressurizing the inside of the container, and (d) a step of discharging the gas hydrate pellets cooled from the depressurized container under normal pressure, so that the gas hydrate pellets are reduced while suppressing the generation of purge gas. It can be discharged from the high pressure gas hydrate product gas into a storage tank under normal pressure.

  In addition, as described above, since the gas hydrate pellets are directly cooled by charging the gas hydrate pellets into the container into which the refrigerant liquid is injected, the present invention can instantaneously cool the gas hydrate pellets. .

  In addition, the invention according to claim 2 has at least three containers for discharging the gas hydrate pellets and sequentially performs the steps (a) to (d) while shifting the time between the containers. Gas hydrate pellets can be continuously dispensed.

  In the invention according to claim 3, since the refrigerant gas generated when the refrigerant liquid is extracted from the gas hydrate pellet discharge container is reliquefied using the cold heat of the liquefied natural gas, the refrigeration that consumes electric power. This eliminates the need for a machine and is economical.

  A gas hydrate pellet dispensing apparatus according to a fourth aspect of the present invention is the gas hydrate pellet dispensing apparatus for dispensing gas hydrate pellets from a high-pressure gas hydrate product gas to a storage tank under normal pressure. A container for discharging the basic gas hydrate pellet, a refrigerant supply valve for sequentially distributing the refrigerant liquid to the container, and a gas hydrate pellet input for charging the gas hydrate pellet into the container into which the refrigerant liquid has been injected A valve, a pressure reducing valve for discharging the refrigerant liquid from the container charged with the gas hydrate pellets, a gas hydrate pellet discharging valve for discharging the gas hydrate pellets of the decompressed container under normal pressure, and the pressure reducing valve And a refrigerant reliquefier that reliquefies the refrigerant gas that has been vaporized when the pressure is reduced. In, it has become possible to use the the depressurizing device and the cooler which cools depressurized the gas hydrate pellets is molded in an atmosphere of high pressure gas in a single container.

  Accordingly, the process of the gas hydrate pellet dispensing apparatus is shortened accordingly, and maintenance and management can be easily performed.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In this embodiment, the case where the mixing container is switched by a triple system will be described. However, the present invention is not limited to this.

  FIG. 1 is a schematic configuration diagram of an apparatus applied to the implementation of the gas hydrate pellet dispensing method of the present invention.

  In FIG. 1, reference numeral 1 denotes a gas hydrate pellet dispensing device, which includes a table feeder 2, three mixing containers 3a, 3b, 3c, a screw feeder 4, a refrigerant reliquefier 5, a buffer tank 6, and a liquid feed pump. 7 is provided.

  The mixing containers (gas hydrate pellet discharge containers) 3a to 3c are respectively a liquid injection valve (refrigerant supply valve) 11, a gas hydrate pellet injection valve 12, a pressure reducing valve (also referred to as a extraction valve) 13, and a gas. A hydrate pellet discharge valve 14 is provided.

  The liquid injection valve 11 is provided in each of the three branch pipes 16a, 16b, and 16c branched from the refrigerant supply pipe 15 connected to the refrigerant reliquefier 5. The first branch pipe 16a is connected to the first mixing container 3a, the second branch pipe 16b is connected to the second mixing container 3b, and the third branch pipe 16c is connected to the third mixing container 3b. It is connected to the container 3c.

  Moreover, the gas hydrate pellet input valve 12 is provided in three gas hydrate pellet input pipes 17a, 17b, and 17c communicating with the table feeder 2 and each mixing container 3a, 3b, 3c. The pressure reducing valve 13 is connected to the first extraction pipe 18a provided in the first mixing container 3a, the second extraction pipe 18b provided in the second mixing container 3b, and the third mixing container 3c. The third extraction pipe 18c is provided. The three extraction pipes 18a to 18c are connected to a trunk pipe 19 provided in the refrigerant reliquefier 5, respectively. The gas hydrate pellet discharge valve 14 is provided in each of the three gas hydrate pellet discharge pipes 20a, 20b, and 20c communicating with the mixing containers 3a, 3b, and 3c and the screw feeder 4.

Note that the buffer tank 6 and the liquid feed pump 7 for temporarily storing the refrigerant reliquefied by the refrigerant reliquefier 5 are provided in the refrigerant supply pipe 15. Further, in this embodiment uses a propane (C ₃ H ₈₎ as a refrigerant liquid is not limited thereto, for example, can be applied butane (C ₄ H _10).

  The table feeder 2 distributes the gas hydrate pellets p supplied from the hopper 21 to a plurality of mixing containers 3a, 3b, 3c. The three gas hydrate pellet discharge parts 24a, 24b, and 24c are projected (see FIG. 2). Gas hydrate pellet input pipes 17a, 17b, and 17c equipped with the gas hydrate pellet input valve 12 are connected to the gas hydrate pellet discharge sections 24a, 24b, and 24c.

  The screw feeder 4 includes a cylindrical main body 31 and a screw part 32 inserted into the main body 31, and the screw part 32 is driven by an electric motor 33. And the gas hydrate pellet p discharged | emitted from this screw feeder 4 is stored in the storage tank which is not shown in figure.

  As shown in FIG. 3, the first, second, and third mixing containers 3a, 3b, and 3c include (a) a refrigerant liquid filling step A, (b) a gas hydrate pellet charging and cooling step B, (c The four steps of the refrigerant removal step C and (d) the gas hydrate pellet discharge step D are defined as one cycle, and one cycle is executed at a predetermined time t (for example, 60 seconds).

Further, the processing time of the refrigerant liquid filling step A is t ₁ seconds (for example, 20 seconds), the processing time of the gas hydrate pellet charging and cooling step B is t ₂ seconds (for example, 20 seconds), and the refrigerant removing step. The processing time of C is t ₃ seconds (for example, 10 seconds), and the processing time of the gas hydrate pellet discharging process D is t ₄ seconds (for example, 10 seconds).

The first, second, third mixing vessel 3a, 3b, 3c is adapted to operate at t ₁ second delay.

  Next, the operation of the gas hydrate pellet dispensing apparatus will be described. For convenience, the operation of the first mixing container will be described.

(1) First, as shown in FIG. 4A, a refrigerant liquid (liquefied propane (C ₃ H ₈ )) cooled to a predetermined temperature (for example, about −30 ° C.) in the first mixing container 3a. injecting m (injection time: t ₁ seconds).

  In this case, only the liquid injection valve 11 is “open”, and the other valves, that is, the gas hydrate pellet input valve 12, the pressure reducing valve 13, and the gas hydrate pellet discharge valve 14 are all “closed”. . In this case, the pressure in the 1st mixing container 3a is 2.5ata (0.245MPa).

(2) Next, as shown in FIG. 4B, the injection valve 11 is switched from “open” to “closed”, and then the gas hydrate pellet input valve 12 is switched from “closed” to “open”. When switched, the gas hydrate pellet p is charged into the first mixing container 3a from the table feeder 2 already described (charging time: t ₂ seconds).

  The gas hydrate pellets p charged into the first mixing container 3a are rapidly cooled to a temperature (for example, about −20 ° C.) at which the self-preserving effect can be exhibited by the refrigerant liquid m, and at the same time, the first mixing container 3a. Since a high-pressure (for example, 54 ata (5.29 MPa)) source gas (gas hydrate product gas) g flows in with the gas hydrate pellets p, the pressure in the first mixing vessel 3a increases (for example, , 54 data (5.29 MPa)).

  (3) Next, as shown in FIG. 4C, the gas hydrate pellet injection valve 12 is switched from “open” to “closed”. Thereafter, when the pressure reducing valve 13 is switched from “closed” to “open”, the refrigerant liquid m in the first mixing container 3a flows out through the pressure reducing valve 13, and the first mixing container 3a is depressurized ( For example, 1.75 data (0.17 MPa)).

The discharge time of the refrigerant liquid is t ₃ seconds. Further, the refrigerant gas vaporized when the pressure is reduced by the pressure reducing valve 13 is reliquefied by the refrigerant reliquefier 5 using LNG (u) as a cold heat source.

  (4) Next, as shown in FIG. 4D, the pressure reducing valve 13 is switched from “open” to “closed”, and then the gas hydrate pellet discharge valve 14 is switched from “closed” to “open”. Then, the gas hydrate pellets p remaining in the first mixing container 3a are discharged through the gas hydrate pellet discharge valve 14. The gas hydrate pellets p discharged from the first mixing container 3a are stored in a storage tank (not shown) installed at normal pressure by the screw feeder 4.

  FIG. 5 is a state diagram of the refrigerant (propane), and reference numerals a to c denote a high-pressure (54 ata) gas hydrate product gas g flowing into the mixing container 3a and at the same time being introduced into the mixing container 3a. The transition state of the refrigerant liquid (propane) m previously filled in the mixing container 3a is shown by the sensible heat of the gas hydrate pellets p.

  Symbols c to d indicate a situation where the refrigerant liquid (propane) m in the mixing container 3a is decompressed, and symbols d to e indicate a situation where the refrigerant liquid (propane) m is gasified. Symbols e to a indicate a state in which the refrigerant (propane) that has been cooled and gasified by LNG or the like is reliquefied.

  Moreover, the code | symbol e illustrates the state which became the liquid from the gas-liquid state of the code | symbol d. Therefore, symbols d to e are cooling loads due to LNG.

It is a schematic block diagram of the apparatus applied to implementation of the discharge method of the gas hydrate pellet of this invention. It is a plane sectional view of a table feeder. It is a cycle pattern figure which shows the switching cycle of a mixing container. (A) The figure which shows the filling process of a refrigerant liquid, (b) The figure which shows a gas hydrate pellet injection | throwing-in and cooling process, (c) The figure which shows the liquid draining process of a refrigerant liquid, (d) The discharge process of a gas hydrate pellet FIG. It is a state diagram of a refrigerant (propane). It is a general view of a prior art example.

Explanation of symbols

g High-pressure gas hydrate product gas m Refrigerant liquid p Gas hydrate pellets 1 Gas hydrate pellet dispenser 3a to 3c Mixing container (container for dispensing gas hydrate pellets)
5 Refrigerant reliquefier 11 Injection valve (refrigerant supply valve)
12 Gas hydrate pellet injection valve 13 Pressure reducing valve (extraction valve)
14 Gas hydrate pellet discharge valve

Claims (4)

In the method for dispensing gas hydrate pellets, the gas hydrate pellets are dispensed from a high-pressure gas hydrate product gas into a storage tank under normal pressure.
(A) injecting a refrigerant liquid into a container for discharging gas hydrate pellets;
(B) introducing the gas hydrate pellets into the container into which the refrigerant liquid has been injected to cool the gas hydrate pellets;
(C) extracting the refrigerant liquid from the container to depressurize the container;
(D) A method for dispensing gas hydrate pellets, which comprises a step of dispensing gas hydrate pellets cooled from a decompressed container under normal pressure. 2. The gas hydrate according to claim 1, wherein the gas hydrate pellet discharge container has at least three containers, and the steps (a) to (d) are sequentially performed while shifting the time between the containers. How to dispense pellets. 2. The method for delivering gas hydrate pellets according to claim 1, wherein the refrigerant gas generated when the refrigerant liquid is withdrawn from the container for delivering gas hydrate pellets is reliquefied using the cold of liquefied natural gas. In a gas hydrate pellet dispensing apparatus for dispensing gas hydrate pellets from a high-pressure gas hydrate product gas to a storage tank under normal pressure, at least three containers for discharging gas hydrate pellets and a refrigerant liquid in the container A refrigerant supply valve that distributes in order, a gas hydrate pellet introduction valve that introduces the gas hydrate pellets into the container into which the refrigerant liquid has been injected, and a refrigerant liquid that is discharged from the container into which the gas hydrate pellets have been introduced A pressure reducing valve, a gas hydrate pellet discharge valve for discharging the gas hydrate pellets of the decompressed container under normal pressure, and a refrigerant reliquefier for reliquefying the refrigerant gas vaporized when the pressure is reduced by the pressure reducing valve A gas hydrate pellet dispensing device comprising.

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