JP2003285793A - Gas hydrate pellet storing equipment on sea - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To develop storage equipment on the sea, such as a storage tank necessary for storage and transport of NGP, a device to effect loading in the tank, and a discharging device. <P>SOLUTION: Gas hydrate pellet storing equipment on the sea is formed such that a floating body structure 1 on the sea is constituted that a partition consisting of a double bulkhead, an independent tank 6 the outer surface of which is covered by a heat insulation material is situated in the partition, the independent tank 6 comprises a tank side wall 10; and upper wall where a plurality of upper unit walls 15 situated at a tank side wall 10 and the upper parts of the tank side wall 10 and formed in an inverted funnel-shape and having an input port 14 formed in a top part are combined together; and a bottom wall where a plurality of unit bottom walls 17 having a discharge port formed in a funnel-shape and in a lower end part are combined together, the unit bottom walls 17 of which the bottom wall consists are formed in a larger number than the number of the unit upper walls 15. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas hydrate pellet storage facility for pelletizing and storing so-called gas hydrate, which is composed of a gas mainly containing methane such as natural gas and water. It is about.

[0002]

2. Description of the Related Art Conventionally, the storage of natural gas is liquefied natural gas.
(Hereinafter referred to as LNG) or compressed natural gas.

However, LNG needs to be stored while keeping the cargo temperature at an ultralow temperature of minus 162 ° C., and a storage facility having an expensive tank specially manufactured for the storage is required.

In addition, LNG has a natural gas of minus 16
In order to make a liquid at 2 ° C, it is necessary to invest a lot of energy in its production. Further, LNG is extremely dangerous because it vaporizes rapidly when the temperature control becomes poor. Moreover, LNG has a high vaporization rate and is not suitable for long-term storage due to the extremely low temperature as described above.

On the other hand, as a clean energy source and a raw material of various structures, a gas containing methane as a main component such as natural gas has attracted attention, and for the purpose of transporting and storing the gas, the gas containing this natural gas as an artificial component has been artificially produced. Studies have been conducted on a gas hydrate (hereinafter, referred to as NGH) either industrially or industrially.

[0006] NGH is simply a molecule of water.
A crystal in which each gas molecule is contained in the basket
Has a structure, for example, in methane hydrate,
1m ³164m during methane hydrate³Includes methane
It is said that it can be stored. Among them, the volume of water is 0.
8m³Is.

[0007] As described above, methane hydrate has a high gas encapsulation property, and therefore has attracted attention as a new transport and storage body for natural gas, which replaces LNG. Methane gas density in methane hydrate is about 3.5 of LNG.
Although it is one-third, when it is manufactured artificially or industrially, it is not necessary to cool it to a liquefaction temperature (minus 162 ° C or lower) unlike LNG, so that energy efficiency is significantly improved. It is said.

In the case of artificially producing methane hydrate, for example, the temperature is 1 to 10 ° C. and the pressure is 30 to 100.
By supplying methane gas into the water in the pressure vessel kept at atmospheric pressure or spraying water or antifreeze liquid into the methane gas from the spraying means, the water or antifreeze liquid and natural gas (methane) are synthesized to produce powdery methane hydrate. Is generated.

Since this powdery methane hydrate has a small filling rate (volume / storage amount of methane hydrate), it must be formed into a pellet-like solid matter by a granulator such as a pelletizer during transportation or storage. Is being considered.

On the other hand, a gas hydrate pellet manufacturing apparatus (hereinafter referred to as NGH pellet) having such characteristics is suitable for a small-scale gas field because it is relatively small and inexpensive.

Therefore, when the natural gas obtained from this small-scale gas field is transported to the place of consumption as NGH pellets, the manufactured NGH pellets are once stored until they reach a predetermined amount, and then loaded on a ship. Need to be transported to the place of consumption.

[0012]

Therefore, it is desired to develop a storage tank necessary for storing and transporting the NGH pellets and a storage facility such as a loading device and a discharging device for the NGH pellets in the storage tank. .

[0013]

The present invention has been made in view of the above circumstances and has the following features.

1. According to the first aspect of the present invention, the offshore floating structure is constructed so that at least the side surface and the bottom surface form a compartment constituted by a double shell wall, and the outer surface is covered with a heat insulating material in the compartment. And arrange the independent tank,
An upper wall formed by combining a plurality of unit upper walls having a tank side wall and an upper portion of the tank side wall and having an inverted funnel shape and an inlet at the top, and a lower wall of the tank side wall, having a funnel shape and discharging to the lower end portion. An offshore gas hydrate pellet storage facility is provided which is composed of a plurality of unit bottom walls having an outlet and is connected to a plurality of unit bottom walls constituting the bottom wall. It is something to do.

According to the gas hydrate pellet storage facility having the above structure, not only the volume of the independent tank arranged in the section of the offshore floating structure can be increased, but also the safety of the independent tank is improved. You can

2. According to the second aspect of the present invention, the offshore floating structure is configured so that at least the side surface and the bottom surface thereof form a compartment constituted by a double shell wall, and the outer surface is covered with a heat insulating material in the compartment. And arrange the independent tank,
An upper wall formed by connecting a plurality of unit upper walls having a tank side wall and an upper portion of the tank side wall and having an inverted funnel shape and a charging port at the top and a lower wall of the tank side wall and having a funnel shape and a discharge port at the lower end thereof. A unit bottom wall having a plurality of unit bottom walls joined together, wherein the unit bottom wall constituting the bottom wall is combined with a larger number than the unit upper wall constituting the upper wall, and a gas hydrate production apparatus A gas hydrate pellet storage facility equipped with a gas hydrate pellet manufacturing apparatus comprising a granulating apparatus for pelletizing the gas hydrate manufactured by the gas hydrate manufacturing apparatus.

Such a gas hydrate pellet storage facility uses natural gas produced from a gas field in the sea
Applicable when storing as GH pellets.

3. In the invention according to claim 3, the offshore floating structure is configured so that at least the side surface and the bottom surface form a compartment constituted by a double shell wall, and the outer surface is covered with a heat insulating material in the compartment. And arrange the independent tank,
An upper wall formed by combining a plurality of unit upper walls having a tank side wall and an upper portion of the tank side wall and having an inverted funnel shape and a charging port at the top and a funnel shape arranged at the lower portion of the side wall and having a discharge port at the lower end portion. The unit bottom wall having a plurality of unit bottom walls is combined with the unit bottom wall forming the bottom wall, and the unit bottom wall forming the upper wall is connected more than the unit upper wall forming the upper wall. The apparatus includes a first transfer device having one end connected to the gas hydrate pellet supply device and the other end connected to the receiving device, and a plurality of first transfer devices having one end connected to the receiving device and the other end connected to the charging port. It is a gas hydrate pellet storage facility composed of two transfer devices.

According to the gas hydrate pellet storage facility constructed as described above, the NGH pellets are transported to the receiving device by the first transport device, and are distributed to the plurality of second transport devices where they are predetermined. It will be loaded into the independent tank from the input port.

4. According to a fourth aspect of the present invention, an offshore floating structure is configured so that at least the side surface and the bottom surface thereof form a compartment constituted by a double shell wall, and the outer surface is covered with a heat insulating material in the compartment. And an upper wall formed by connecting a plurality of unit upper walls having an inverted funnel shape and having a charging port at the top, the independent tank being disposed on the tank side wall and an upper portion of the tank side wall, and the tank side wall. The unit bottom wall is formed by arranging a plurality of unit bottom walls each having a funnel shape at the lower end and having a discharge port at the lower end thereof, and the bottom wall is a unit constituting the upper wall. A passage, which is connected to the upper wall in a larger number, forms a passage between the bottom wall and the bottom surface of the offshore floating structure that is shielded from outside air and communicates with the discharge port, and the discharge device is provided in the passage. Guy hydrate pellet storage facility.

According to the gas hydrate pellet storage facility configured as described above, when loading and unloading NGH pellets, there is no risk of vaporized gas leaking.

5. Further, the invention according to claim 5 is the gas hydrate pellet storage facility in which the offshore floating structure is a ship.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a gas hydrate pellet storage facility according to the present invention will be described below with reference to FIGS.

FIG. 1 is a longitudinal sectional view of a ship 1 as a floating structure of a gas hydrate pellet storage facility.
3 is a plan view thereof, and FIG. 3 is a cross-sectional plan view taken along the line AA of FIG.

In these figures, 2 is a side wall forming a side surface of the vessel 1, 3 is a partition wall, and 4 is a ship bottom forming a bottom surface. The side wall 2, the partition wall 3 and the ship bottom 4 make the ship 1
A plurality of (five in the illustrated example) bays 5 are formed in the front-rear direction, and an independent tank 6 is arranged in each bay 5.

More specifically, as shown in FIG.
The side wall 2 constituting the above is arranged by the side tank 7, and the bottom 4 is provided with the bottom tank 8 and the bottom side tank 9 so as to maintain the strength of the ship 1 as a so-called double shell, and further, the outer plate 1
Even if a is damaged, seawater is prevented from flowing into the hold 5. In addition, the gas leak from the independent tank 6 is not released to the atmosphere.

An independent tank 6 placed in this hold 5
Is composed of a tank side wall 10, an upper wall 11 and a bottom wall 12, the inside of which can be filled with an inert gas or natural gas, and the outer surface of which is covered with a heat insulating material 13. A rib for reinforcing the tank 6 may be provided inside the tank 6 if necessary.

The upper wall 11 has an inverted funnel shape having an inclination angle α substantially the same as the angle of repose of the NGH pellets, and a plurality of units each having a charging port 14 at the top for loading the NGH pellets. As shown in FIG. 2, the upper walls 15a to 15d are connected to each other in the front-rear direction and the left-right direction. Further, the bottom wall 12 has a plurality of unit bottom walls 17a to 17h each having a funnel shape having an inclination angle β and having a discharge port 16 at a lower end portion thereof, as shown in FIG. It is configured by arranging two and connecting them.

That is, the unit upper wall 1 constituting the upper wall 11
5a to 15d are four in one tank 6, whereas the unit bottom walls 17a to 17h constituting the bottom wall 12 are increased by a doubled number. This doubles the number of outlets 16 than the number of inlets 14, and as a result, it is possible to reduce the dead space at the bottom of the hold 5.

Then, between the independent tank 6 and the bottom wall 12 thus constructed, as shown in FIGS. 3, 4 and 5, an opening 18 provided in the lower portion of the partition wall 3 is penetrated. And the passage 19 including the discharge port 16
It is provided to extend in the front-back direction of
A horizontal belt conveyor 20 as a first unloading device is arranged.

The rear end of the horizontal belt conveyor 20 is connected to a unloading conveyor 22 as a third unloading device via a vertical conveyor 21 as a second unloading device. This vertical conveyor 21 has two horizontal parts,
The sandwiching conveyor 22 and the unloading conveyor 22 which vertically sandwich the load between the conveyors and are configured by normal horizontal conveyors.

The interiors of the accommodating portion 19, the vertical conveyor 21 and the unloading conveyor 22 are gas tight, and the interior thereof is filled with an inert gas or natural gas. Reference numeral 23 is a support roller that supports the horizontal belt conveyor 20.

In particular, as shown in FIG. 5, slide doors 25a and 25b which are vertically moved by cylinders 24a and 24b are arranged in the opening 18 formed in the lower portion of the partition wall 3 except when loading and unloading NGH pellets. As shown in FIG. 6, the two belt conveyors passing through the opening 18 are closed by pressing the slide doors 25a and 25b.

As shown in FIG. 4, one end of the independent tank 6 is connected to an NGH pellet supply device (not shown) as a first conveying device, and one end of the independent tank 6 is connected via an expansion joint 26 as a receiving device as a distributing device. Conveyor 28 connected to (tank) 27 and NG in receiving device 27
A conveyor 29 serving as a second transfer device for charging the H pellets into the independent tank 6 is arranged.
The conveyor 29 and the receiving tank 27 constitute a loading device.

Then, the conveyor 28 and the conveyor 2
9 is preferably a screw conveyor, and this conveyor 28, the conveyor 29, and the receiving tank 27
Both are covered with the heat insulating material 30, and the inside thereof is configured to be filled with an inert gas or natural gas.

In the gas hydrate pellet storage facility having the above-mentioned structure, the NGP supply device (not shown) passes through the conveyor 28, the receiving device 27, and the conveyor 29, and is distributed and loaded into the independent tank 6 from the plurality of inlets 14.

At this time, since the upper wall 11 is composed of four unit upper walls 15a to 15d having an inverted funnel shape, the dead space in the upper portion of the tank 6 becomes small, and the bottom wall 12 also has a funnel-shaped unit bottom. Since it is composed of the walls 17a to 17h, the dead space in the lower part is also small.
Therefore, the storage amount of NGH pellets in the independent tank 6 can be increased. In addition, the inclination angle α of the upper walls 15a to 15d depends on the NGH accommodated inside the tank 6.
It corresponds to the angle of repose of the pellets.

When loading the NGH pellets in the independent tank 6 in this way, after opening the slide gates 25a and 25b, the horizontal belt conveyor 20, the vertical conveyor 21, and the unloading conveyor 2 which are unloading devices.
By driving 2 and 2, NGH pellets can be loaded and unloaded from the discharge port 16 by this unloading device.

FIG. 7 shows another embodiment,
Reference numeral 31 is a floating body as a floating body structure.
1 is provided with a predetermined number of compartments similar to those described in the above embodiment, an independent tank 6 is arranged in each compartment, and an NG comprising a gas hydrate manufacturing apparatus and a granulating apparatus is provided.
An H-pellet manufacturing apparatus 32 is installed.

The floating body 31 is moored to the buoy 34 by the mooring line 33. 35 is a mooring line for mooring the buoy 34, 36 is a riser pipe for taking out the natural gas G from the seabed gas field D, and 37 is a gas pipe for guiding the natural gas G to the floating body 31.

In such a structure, the natural gas G obtained from the seabed gas field D is supplied to the riser pipe 36 and the gas pipe 3.
After being supplied to the NGA pellet manufacturing apparatus 32 mounted on the floating body 31, the NGH pellets manufactured here are temporarily stored in the independent tank 6. And this NG
When the storage amount of H pellets reaches a predetermined amount, this NHP
The pellets are transferred while being stored and transported to a ship 1 that is transported to a predetermined consumption place.

This hydrate pellet storage facility is suitable for storage and transportation of natural gas from a relatively small-scale offshore gas field D.

[0043]

As is apparent from the above description, according to the gas hydrate pellet storage facility of the present invention,
Not only can the safety of the independent tank be improved by constructing the floating body as a double shell, but the independent tank can also be placed in the upper part of the side wall of the tank to form a reverse funnel shape with a plurality of inlets at the top. The unit upper wall is connected to the bottom wall of the tank side wall, and the bottom wall is formed by connecting a plurality of unit bottom walls having a funnel shape and a discharge port at the lower end. Since the number of unit bottom walls constituting the upper wall is larger than the number of unit upper wall constituting the upper wall, the dead space in the compartment can be reduced, resulting in efficient storage of NGH pellets. effective.

[Brief description of drawings]

FIG. 1 is a longitudinal sectional view of a ship as an example of a floating structure used in a gas hydrate pellet storage facility according to the present invention.

FIG. 2 is a plan view of FIG.

3 is a cross-sectional plan view taken along the line AA of FIG.

FIG. 4 is a view taken along the line BB of FIG.

FIG. 5 is an enlarged side view of an opening of a side wall.

6 is an explanatory view of closing the opening in FIG.

FIG. 7 is a schematic side view of an embodiment of a gas hydrate pellet storage facility according to the present invention.

[Explanation of symbols]

1 ... Vessel 2 ... Sidewall 3 ... Bulkhead 4 ... Ship bottom 5 ... Hold 6 ... Independent tank 7 ... Side tank 8 ... Bottom tank 9 ... Bottom side Part tank 10 ... Tank side wall 11 ... Upper wall 12 ... Bottom wall 13, 30 ... Heat insulating material 14 ... Input ports 15a to 15d ... Unit upper wall 16 ... Discharge port 17a -17h ... Unit bottom wall 18 ... Opening 19 ... Passage 20 ... Horizontal belt conveyor 21 ... Vertical conveyor 22 ... Unloading conveyor 23 ... Support rollers 4a, 24b ... Cylinder 25a, 25b ... Sliding door 26 ... Expansion joint 27 ... Receiving tank 28, 29 ... Conveyor 31 ... Floating body 32 ... NGH pellet manufacturing device 33, 35.
..Mooring lines 34 ... Buoys 36 ... Riser pipes 37 ... Gas pipes

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) C10L 3/06 F17C 11/00 B F17C 11/00 C10L 3/00 A (72) Inventor Nao Ishiyama Chiba Prefecture 1 Hachiman Kaigan Dori, Ichihara Mitsui Shipbuilding Co., Ltd. Chiba Works F Term (reference) 3E070 AA02 AA19 AB15 DA01 GA04 GA05 GA11 GA20 HA03 NA01 QA20 WF12 WF14 3E072 AA03 EA10

Claims (5)

[Claims] 1. An offshore floating structure is constructed so that at least its side surface and bottom surface form a compartment constituted by a double shell wall, and an independent tank whose outer surface is covered with a heat insulating material is arranged in the compartment. , The independent tank is arranged in the shape of an inverted funnel arranged on the side wall of the tank and on the upper side of the tank side wall, and is arranged under the tank side wall and an upper wall formed by combining a plurality of unit upper walls having a charging port at the top, and is formed in a funnel shape. And a bottom wall formed by combining a plurality of unit bottom walls each having a discharge port at a lower end thereof, and a plurality of unit bottom walls forming the bottom wall are arranged more than the unit upper wall forming the upper wall. The gas hydrate pellet storage facility on the ocean characterized by the above. 2. An offshore floating structure is constructed so that at least its side surface and bottom surface form a compartment constituted by a double shell wall, and an independent tank whose outer surface is covered with a heat insulating material is arranged in the compartment. , The independent tank is arranged in the upper part of the tank side wall and the upper part of the tank side wall, and is in the shape of an inverted funnel. The unit bottom wall having a plurality of unit bottom walls each having a discharge port at its lower end is connected to the unit bottom wall, and the unit bottom wall forming the bottom wall is connected in a larger number than the unit upper wall forming the upper wall. A gas hydrate pellet production apparatus comprising a rate production apparatus and a granulation apparatus for pelletizing the gas hydrate produced by the gas hydrate production apparatus. Toperetto storage facility. 3. An offshore floating structure is constructed so that at least its side surface and bottom surface form a compartment constituted by a double shell wall, and an independent tank having an outer surface covered with a heat insulating material is arranged in the compartment. The independent tank has a funnel shape which is arranged below the tank side wall and an upper wall formed by connecting a plurality of unit upper walls that are arranged on the tank side wall and an upper portion of the tank side wall and have an inlet at the top. Further, the unit bottom wall having a plurality of unit bottom walls having a discharge port at the lower end portion is composed of a bottom wall, and the unit bottom wall forming the bottom wall is connected in a larger number than the unit upper wall forming the upper wall and is loaded on the independent tank. And a loading device, one end of which is connected to the gas hydrate pellet feeding device and the other end of which is connected to the receiving device, and one end of which is connected to the receiving device and the other end of which is a charging port. Multiple linked to Second transport device and the gas hydrate pellets storage facility, wherein more that are configured. 4. An offshore floating structure is constructed so that at least its side surface and bottom surface form a compartment constituted by a double shell wall, and an independent tank having an outer surface coated with a heat insulating material is arranged in the compartment. A bottom wall of the tank side wall and a bottom wall of the tank side wall and an upper wall formed by connecting a plurality of unit upper walls arranged in an upper portion of the tank side wall and having an inverted funnel shape and a charging port at the top. Is a funnel-shaped unit bottom wall having a plurality of unit bottom walls connected to each other and having a discharge port at its lower end. The unit bottom wall constituting the bottom wall is a unit upper wall constituting the upper wall. More than that, forming a passage communicating with the discharge port between the bottom wall and the bottom surface of the offshore floating structure, and a discharge device is provided in the passage. Storage equipment. 5. The gas hydrate pellet storage facility according to claim 1, wherein the offshore floating structure is a ship.