JP2022094607A - Carbon dioxide transport container, carbon dioxide transportation method, and carbon dioxide discharging method - Google Patents

Abstract

To provide a carbon dioxide transport container, etc., in which the carbon dioxide contained inside can be discharged in a short time, substantially completely.SOLUTION: According to the present invention, a carbon dioxide transport container (2) includes a container body (4) arranged in a rigid outer support part (1). The container body includes: a rigid cylindrical tank part (8); a carbon dioxide-receiving flexible inner tube (10) having a balloon shape, arranged in the tank part while an intake port is connected to one end of the tank part, and capable of being expanded/contracted in the tank part; and pressing devices (23, 42, 44) arranged in the other end side of the inner tube in the tank part, and configured to push the inner tube toward the one end side of the tank part. Thus, the carbon dioxide transport container is provided.SELECTED DRAWING: Figure 1

Description

The present invention relates to a carbon dioxide transport container, a carbon dioxide transport method, and a carbon dioxide emission method, and in particular, uses a relatively small capacity carbon dioxide transport container, which is about the size of a container, and such a container. It relates to a method of transporting carbon dioxide and a method of discharging carbon dioxide from such a container.

From the viewpoint of preventing global warming, the release of carbon dioxide into the atmosphere has become a problem. In order to deal with such a problem, it has been proposed to collect and store carbon dioxide generated in a thermal power plant or the like.

In general, the storage area for storing carbon dioxide is often located away from the place where carbon dioxide is generated such as a thermal power plant. Therefore, it is necessary to transport carbon dioxide recovered from a thermal power plant or the like to a remote storage area, and in some cases, this transportation may be marine transportation.

From the viewpoint of transportation efficiency, it is desirable to transport such carbon dioxide in a large-capacity container or tank.

However, the place where carbon dioxide is generated or the place where carbon dioxide is stored may be located in a place where it is difficult to bring in such a large-capacity container or tank. In such a case, for example, it is necessary to prepare a large number of containers or tanks having a small capacity, such as a container used for freight transportation, and store carbon dioxide in these to transport carbon dioxide. Since carbon dioxide is transported in a high pressure state from the viewpoint of transport efficiency, it is desirable to use a metal pressure-resistant container as the container or tank used for the transport.

In a conventional container or tank, when carbon dioxide is discharged from the container or tank, when the pressure of the carbon dioxide in the container or tank is higher than the atmospheric pressure, the carbon dioxide self-sprays from the container or tank, but in the container or tank. When the pressure of carbon dioxide becomes almost equal to the atmospheric pressure, the self-injection of carbon dioxide from the container or tank stops.

On the other hand, from the viewpoint of preventing global warming, it is desired that carbon dioxide contained in the container or tank is substantially completely discharged from the container or tank without remaining in the container or tank. Therefore, it is conceivable that carbon dioxide is completely discharged from the container or tank by purging the container or tank with a fluid such as water.

However, in the above discharge method, a liquid such as water is injected into each of a large number of containers or tanks to completely discharge carbon dioxide, and then the liquid is discharged from the containers or tanks. Therefore, there is a problem that the time required for the carbon dioxide emission work becomes long.

The present invention has been made in view of such a point, and an object of the present invention is to provide a carbon dioxide transport container capable of substantially completely discharging carbon dioxide contained therein in a short time.

Another object of the present invention is to provide a carbon dioxide transport method using a carbon dioxide transport container, which can easily discharge the carbon dioxide contained therein in a substantially short time.

Furthermore, it is an object of the present invention to provide a carbon dioxide discharging method capable of discharging carbon dioxide from a carbon dioxide transport container in a short time.

According to the present invention
A container for transporting carbon dioxide
Equipped with a container body placed inside a rigid outer support
The container body
Rigid tubular tank part and
A flexible inner tube for accommodating carbon dioxide, which has a balloon shape and is arranged in the tank portion with a blow port connected to one end of the tank portion and can be expanded and contracted in the tank portion.
A pressing device arranged on the other end side of the inner tube in the tank portion and configured to press the inner tube toward one end side of the tank portion is provided.
A container for transporting carbon dioxide is provided.

According to such a configuration, when the high-pressure carbon dioxide contained in the inner tube is discharged from the inlet of the inner tube, when the pressure of the carbon dioxide in the inner tube becomes close to the atmospheric pressure. By operating the pressing device in the tank portion and pressing and contracting the inner tube, the carbon dioxide remaining in the inner tube can be efficiently discharged. As a result, the carbon dioxide contained in the inner tube can be discharged in a short time.

According to another preferred embodiment of the invention.
The pressing means has a degassing tube that can be expanded and contracted in the tank portion.
The degassing tube can be expanded to a volume that fills the internal space of the tank portion.

According to such a configuration, by expanding the degassing tube to a volume that fills the internal space in the tank portion, it is possible to substantially completely discharge the carbon dioxide contained in the inner tube in a short time.

According to another preferred embodiment of the invention.
The pressing means has an extrusion plate arranged in the tank portion so as to be orthogonal to the longitudinal axis of the tank, and an extrusion rod that presses the extrusion plate toward one end of the tank portion.

According to such a configuration, by moving the extrusion plate to one end of the tank portion by the extrusion rod, it is possible to substantially completely discharge the carbon dioxide contained in the inner tube in a short time.

According to another preferred embodiment of the invention.
The tank portion has a tubular shape including a splittable upper half portion and a lower half portion.

According to such a configuration, since the tank portion can be divided, when carbon dioxide is not contained, it can be disassembled, transported, stored, and the like, and space saving is realized.

According to another preferred embodiment of the invention.
The tank portion further has a cap portion arranged on one end side and having an opening for carbon dioxide inlet / outlet.
The carbon dioxide inlet / outlet of the inner tube is attached to the carbon dioxide inlet / outlet opening of the cap portion.

According to another preferred embodiment of the invention.
The outer support is a freight transport container.

According to such a configuration
It will be possible to transport carbon dioxide using existing freight containers.

According to another preferred embodiment of the invention.
The outer support is a substantially rectangular rigid frame.

According to another preferred embodiment of the invention.
The rigid frame is an assembly type.

According to such a configuration
When storing and transporting a carbon dioxide transport container without accommodating carbon dioxide, the outer support can be disassembled for storage and transport, thus saving space.

According to another preferred embodiment of the invention.
The tank portion further includes a reinforcing bracket that connects each of the facing corner portions of the outer support to the tank portion.

According to such a configuration
Since the tank body can be fixed in the outer support of a freight transport container or the like, it is possible to prevent deformation due to external force applied to the tank body.

According to another aspect of the invention.
Provided is a carbon dioxide transport method in which a pressurized carbon dioxide is filled in an inner tube of any of the above carbon dioxide transport containers and transported.

According to another aspect of the invention.
A method of discharging carbon dioxide from any of the above carbon dioxide transport containers.
It comprises a step of discharging carbon dioxide from the inner tube while activating the pressing device to press the inner tube.
A carbon dioxide emission method characterized by this is provided.

According to the present invention, there is provided a carbon dioxide transport container capable of substantially completely discharging the carbon dioxide contained therein in a short time.

Further, according to the present invention, there is provided a carbon dioxide transport method using a carbon dioxide transport container, which can easily discharge the carbon dioxide contained therein in a substantially short time.

Further, according to the present invention, there is provided a carbon dioxide discharging method capable of discharging carbon dioxide from a carbon dioxide transport container in a short time.

It is a schematic perspective view which shows the structure of the carbon dioxide transport container of the preferable aspect of this invention. It is sectional drawing of the container for transporting carbon dioxide along the line II-II of FIG. It is sectional drawing of the carbon dioxide transport container along the line III-III of FIG. It is a schematic exploded perspective view of the tank part of the carbon dioxide transport container. It is the same schematic cross-sectional view as FIG. 2 of the carbon dioxide transport container explaining the process of filling carbon dioxide into a carbon dioxide transport container. It is a schematic cross-sectional view similar to FIG. 2 of the carbon dioxide transport container for explaining the carbon dioxide discharge process from the carbon dioxide transport container. It is a schematic cross-sectional view similar to FIG. 2 which shows the carbon dioxide filling state of the carbon dioxide transport container of another embodiment of this invention. It is a schematic sectional view similar to FIG. 2 explaining the carbon dioxide discharge process from the carbon dioxide transport container of another embodiment of this invention.

Hereinafter, a carbon dioxide transport container according to a preferred embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic perspective view showing the configuration of a carbon dioxide transport container 2 arranged in a freight transport container 1, and FIG. 2 is a carbon dioxide transport along line II-II of FIG. It is a cross-sectional view of the container 2, and FIG. 3 is a cross-sectional view of the carbon dioxide transport container 2 along the line III-III of FIG. It should be noted that FIGS. 2 and 3 are drawings in a state where carbon dioxide is substantially completely filled inside.

Further, in the present specification, carbon dioxide means not only pure carbon dioxide but also all fluids containing carbon dioxide as a main component.

As the freight transport container 1 which is the rigid outer support portion in the present embodiment, for example, it is preferable to use a freight transport container based on the ISO standard having a rectangular parallelepiped shape manufactured of steel, aluminum or the like. Specific examples thereof include, but are not limited to, a freight transport container having a width of 2.352 m, a height of 2.395 m, and a depth of 12.03 m.

Further, in order to suppress the temperature rise of carbon dioxide inside during transportation, when the carbon dioxide is transported at a low temperature, the freight transport container 1 is a so-called reefer container whose internal temperature can be adjusted. Is good.

The carbon dioxide transport container 2 of the present embodiment is a transport container arranged in such a freight transport container 1 and accommodating high-pressure carbon dioxide inside.

As shown in FIGS. 1 to 3, the carbon dioxide transport container 2 is composed of a container body 4 arranged in the freight transport container 1 and accommodating carbon dioxide.
The container body 4 of the present embodiment has a substantially cylindrical shape with both ends closed, and has dimensions that substantially fill the internal space of the freight transport container 1. Further, the container body 4 is provided with an inlet / outlet 6 for taking in / out carbon dioxide inside on one end side in the longitudinal direction.

The container body 4 includes a rigid tank portion 8 arranged on the outer side and a flexible and stretchable inner tube 10 for accommodating carbon dioxide arranged in the tank portion 8. The tank portion 8 is made of a rigid material such as metal, and has a substantially cylindrical shape in which both ends of the container body 4 are closed.

FIG. 4 is a schematic exploded perspective view of the tank portion 8. As shown in FIG. 4, the tank portion 8 has a cylindrical tank body 16 that can be divided into two parts, an upper half portion 12 and a lower half portion 14, and a cap 18 on one end side that closes one end side of the tank body 16. And the other end side cap 20 for closing the other end side of the tank body 16.

In the present embodiment, the upper half portion 12 and the lower half portion 14 have a semi-cylindrical shape having substantially the same shape, and the flange portions provided on the side edge portions extending outward are connected to each other by bolts or the like. A cylindrical tank body 16 is formed by being connected by a tool (not shown). A shear nut may be used for this connector.

Further, the one end side cap 18 and the other end side cap 20 are provided with a female threaded portion at the outer peripheral end, and the female threaded portion is provided on the male threaded portion formed on the outer periphery of the one end side opening and the other end side opening of the tank body 16. By screwing in, it is attached to the tank body 16 to form the tank portion 8.
Further, the one-end side cap 18 is formed with an opening 22 that constitutes the entrance / exit 6 of the container body 4.

Further, the inner tube 10 is made of a flexible and expandable material such as rubber that does not allow carbon dioxide to be contained, and can be expanded and contracted in the tank portion 8 by moving carbon dioxide in and out of the inner tube 10. It is a balloon-shaped member, and the inner tube 10 has dimensions that fill the internal space of the tank portion 8 when inflated.

Further, the blow port 24 of the inner tube 10 is attached to the opening 22 formed in the cap 18 on one end side of the tank portion 8, and carbon dioxide is introduced into the inner tube 10 from the outside of the container body through the blow port 24. It is configured so that it can be taken in and out.

Since the inner tube 10 can be expanded to a volume larger than the size of the internal space of the tank portion 8, when the inner tube 10 housed in the tank portion 8 is filled with carbon dioxide in a pressurized state, the inner tube 10 is filled. Expands to a size that abuts on the inner peripheral surface of the tank portion 8, and further expansion is restricted by the tank portion 8. Therefore, in this state, the internal pressure of the inner tube 10 is supported by the tank portion 8.

Further, a flexible degassing tube 26 constituting the pressing device is arranged on the other end side of the tank portion 8. That is, the degassing tube 26 is located on the opposite side of the inlet / outlet 6 of the container body 4 with the inner tube 10 interposed therebetween. The degassing tube 26 is also a balloon-shaped member made of a flexible and stretchable material such as rubber and configured to be expandable and contractible in the tank portion 8. Then, by introducing a fluid such as air into the inside, it is configured to be expandable to a volume that fills the internal space of the tank portion 8.

In the present embodiment, the degassing tube 26 is attached to the cap 20 on the other end side of the tank portion 8. A valve (not shown) communicating with the air inlet of the gas vent tube 26 is attached to the cap 20 on the other end side. In this embodiment, a compressor provided outside communicates with the inside of the degassing tube 26 via this valve. The present embodiment is configured so that the high-pressure fluid from the compressor can be introduced into the degassing tube 26 to inflate the degassing tube 26 with the valve open.

Further, in the carbon dioxide transport container 2 of the present embodiment, as shown in FIG. 3, the tank portion 8 has a reinforcing bracket 30 for connecting each of the opposite corner portions of the freight transport container 1 to the tank portion 8. Further prepared.

Specifically, the reinforcing bracket 30 includes a flange receiving adjusting gear unit 31 arranged between the coupling flange 8a provided on the tank portion 8 and the frame fixing portion 1a of the container 1.

As shown in FIG. 3, the flange receiving adjusting gear unit 31 has an adjusting rod 31a having a spiral cut on the outer circumference and rotatable about the longitudinal axis as shown by an arrow A. One end of the adjusting rod 31a is screwed into the coupling flange 8a provided in the tank portion 8, and the other end is screwed into the frame fixing portion 1a of the container 1. This embodiment is configured so that the tension between the coupling flange 8a provided on the tank portion 8 and the frame fixing portion 1a of the container 1 can be adjusted by rotating the adjusting rod 31a.

An adjustment gear 31b that rotates integrally with the adjustment rod 31a is fixed to the adjustment rod 31a.

The flange receiving adjusting gear unit 31 further includes an operating rod 31c whose outer circumference is spirally cut and rotationally driven in the direction of arrow B by a power source (not shown). The spiral portion on the outer circumference of the operating rod 31c meshes with the adjusting gear 31b.
As a result, the rotation of the operating rod 31c is converted into the rotation of the adjusting rod 31a via the adjusting gear 31b, and the tension between the coupling flange 8a provided in the tank portion 8 and the frame fixing portion 1a of the container 1 is increased. It will be adjusted.

Next, the filling of carbon dioxide into the carbon dioxide transport container 2 and the emission of carbon dioxide from the carbon dioxide transport container 2 will be described.

FIG. 5 is a schematic cross-sectional view similar to FIG. 2 of the carbon dioxide transport container 2 in a state where the inside of the inner tube 10 is not filled with carbon dioxide. FIG. 6 is a schematic cross-sectional view similar to FIG. 5 of the carbon dioxide transport container 2 for explaining a state in which carbon dioxide emission from the inner tube 10 is promoted by inflating the degassing tube.

When introducing carbon dioxide into the carbon dioxide transport container 2 (FIG. 5) arranged in the freight transport container 1, a part of the freight transport container 1 is opened and attached to one end side cap 18. For example, carbon dioxide having a pressure of about 200 Bar is introduced into the inner tube 10 from the inlet 24 of the inner tube 10.

When the inner tube 10 expands due to the introduced carbon dioxide and completely fills the internal space of the tank portion 8 (FIG. 2), the introduction of carbon dioxide is completed and the inner tube 10 is provided at the air inlet 24 of the inner tube 10. By closing the high pressure valve, the inlet 24 of the inner tube is closed.

Next, the freight transport container 1 is closed, and the carbon dioxide transport container 2 is transported toward a destination such as a carbon dioxide storage area by a means of transportation such as a truck or a ship.

When the freight transport container 1 is a reefer container or the like whose internal environment such as temperature can be adjusted, transportation is performed while adjusting the internal environment in the freight transport container 1 as appropriate.

When the carbon dioxide transport container 2 containing carbon dioxide arrives at a destination such as a carbon dioxide storage area, carbon dioxide is discharged from the carbon dioxide transport container 2.

As described above, since carbon dioxide is stored in the carbon dioxide transport container 2 in a pressurized state, the pressure of carbon dioxide in the inner tube 10 is increased by opening the air inlet 24 of the inner tube 10. Self-sprays from the entrance / exit of the carbon dioxide transport container 2 until the pressure drops to near the atmospheric pressure.

When the pressure of carbon dioxide in the inner tube 10 drops to a pressure near the atmospheric pressure, the speed of self-injection from the inlet / outlet of the carbon dioxide transport container 2 decreases. As shown in FIG. 6, at this stage, air is blown into the degassing tube as shown by arrow C to inflate it, and the inner tube 10 is directed from the other end side to one end side as shown by arrow D. Press and push the carbon dioxide remaining in the inner tube 10 outward from the doorway as shown by the arrow E.

The expansion of the degassing tube may be started in a state where the pressure of carbon dioxide in the inner tube 10 is higher than the atmospheric pressure.

By expanding the degassing tube to a volume that fills the internal space of the tank portion 8, the carbon dioxide in the inner tube 10 can be discharged almost completely.

Next, the carbon dioxide transport container 40 of another preferred embodiment of the present invention will be described. FIG. 7 is a schematic cross-sectional view similar to FIG. 2 showing a carbon dioxide filling state of the carbon dioxide transport container of another preferred embodiment, and FIG. 8 is from the carbon dioxide transport container of another embodiment. It is a schematic cross-sectional view similar to FIG. 2 explaining the carbon dioxide emission process of.

The carbon dioxide transport container 40 of another preferred embodiment has the same basic configuration as the carbon dioxide transport container 2. The difference between the carbon dioxide transport container 40 and the carbon dioxide transport container 2 is that, instead of the degassing tube 26, a pressing device provided with an extrusion plate 42 and an extrusion rod 44 is provided as a pressing device. Is.

The extruded plate 42 constituting the pressing device of the carbon dioxide transport container 40 is a plate-shaped member having substantially the same dimensional shape as the cross section in the direction orthogonal to the longitudinal axis of the cylindrical tank portion, and the surface of the tank portion is the tank portion. It is arranged at a position on the other end side of the inner tube 10 in the tank portion 8 in an orientation orthogonal to the longitudinal axis of the tank portion 8.

The extrusion rod 44 penetrates the cap 20 on the other end side of the tank portion 8 and extends into the tank portion 8, and its tip is connected to the back surface of the extrusion plate 42 (the surface on the other end side of the tank portion 8). The extrusion rod 44 can be reciprocated along the longitudinal axis of the tank portion 8 by a drive source (not shown), and the extrusion plate 42 is moved from the other end (right end in FIG. 7) to one end (left end in FIG. 7) of the tank portion 8. It is configured so that the inner tube 10 arranged at the position on one end side of the extrusion plate 42 can be pressed and crushed toward the one end side of the tank portion 8.

Next, the filling of carbon dioxide into the carbon dioxide transport container 40 and the emission of carbon dioxide from the carbon dioxide transport container 40 will be described.

Next, the carbon dioxide transport container 40 is filled with carbon dioxide in the same manner as in the case of the carbon dioxide transport container 2 with the extrusion plate 42 arranged at the other end of the tank portion 8 (right end in FIG. 7). , A part of the freight transport container 1 is opened, and carbon dioxide having a pressure of, for example, about 200 Bar is introduced into the inner tube 10 from the inlet 24 of the inner tube 10 attached to the cap 18 on one end side. ..

When the inner tube 10 expands due to the introduced carbon dioxide and completely fills the internal space of the tank portion 8, the introduction of carbon dioxide is completed, and the high-pressure valve provided at the inlet 24 of the inner tube 10 is completed. By closing the inner tube, the air inlet 24 of the inner tube is closed (FIG. 7).

Next, the freight transport container 1 is closed, and the carbon dioxide transport container 40 is transported toward a destination such as a carbon dioxide storage area by a means of transportation such as a truck or a ship.

When the carbon dioxide transport container 40 containing carbon dioxide arrives at a destination such as a carbon dioxide storage area, carbon dioxide is discharged from the carbon dioxide transport container 40.

As described above, since carbon dioxide is contained in the carbon dioxide transport container 40 in a pressurized state, the pressure of carbon dioxide in the inner tube 10 is increased by opening the air inlet 24 of the inner tube 10. Self-sprays from the entrance / exit of the carbon dioxide transport container 40 until the pressure drops to near the atmospheric pressure.

When the pressure of carbon dioxide in the inner tube 10 drops to a pressure near the atmospheric pressure, the speed of self-injection from the inlet / outlet of the carbon dioxide transport container 40 decreases. As shown in FIG. 8, at this stage, the extrusion plate 42 is moved by the extrusion rod 44 as shown by the arrow F, and the inner tube 10 is pressed from the other end side of the tank portion 8 toward one end side. And crush it, and push the carbon dioxide remaining in the inner tube 10 outward from the doorway as shown by the arrow G.

The pressing by the extrusion plate 42 may be started in a state where the pressure of carbon dioxide in the inner tube 10 is higher than the atmospheric pressure.

Not limited to the above-described embodiment of the present invention, various modifications and modifications can be made within the scope of the technical idea described in the claims.

In the description of the carbon dioxide transport container of the above embodiment, the rigid outer support section is a freight transport container, but the outer support section is not limited to the freight transport container, and is an assembly-type rectangular frame. And so on.

1: Freight transport container 2: Carbon dioxide transport container 4: Container body 6: Doorway 8: Tank part 10: Inner tube 12: Upper half part 14: Lower half part 16: Tank body 18: One end side cap 20: Other End side cap 22: Opening 24: Blow port 26: Degassing tube

Claims (10)

A container for transporting carbon dioxide
Equipped with a container body placed inside a rigid outer support
The container body
Rigid tubular tank part and
A flexible inner tube for accommodating carbon dioxide, which has a balloon shape and is arranged in the tank portion with a blow port connected to one end of the tank portion and can be expanded and contracted in the tank portion.
A pressing device arranged on the other end side of the inner tube in the tank portion and configured to press the inner tube toward one end side of the tank portion is provided.
A container for transporting carbon dioxide, which is characterized by that. The pressing means has a degassing tube that can be expanded and contracted in the tank portion.
The degassing tube can be expanded to a volume that fills the internal space of the tank portion.
The carbon dioxide transport container according to claim 1. The pressing means has an extrusion plate arranged in the tank portion so as to be orthogonal to the longitudinal axis of the tank, and an extrusion rod that presses the extrusion plate toward one end of the tank portion.
The carbon dioxide transport container according to claim 1. The tank portion further has a cap portion arranged on one end side and having an opening for carbon dioxide inlet / outlet.
The carbon dioxide inlet / outlet of the inner tube is attached to the carbon dioxide inlet / outlet opening of the cap portion.
The carbon dioxide transport container according to claim 2 or 3. The outer support is a freight transport container.
The carbon dioxide transport container according to any one of claims 1 to 4. The outer support is a substantially rectangular rigid frame.
The carbon dioxide transport container according to any one of claims 1 to 4. The rigid frame is an assembly type.
The carbon dioxide transport container according to claim 6. The tank portion further includes a reinforcing bracket that connects each of the opposite corner portions of the outer support to the tank portion.
The carbon dioxide transport container according to any one of claims 5 to 7. The carbon dioxide transport container according to any one of claims 1 to 8 is filled with pressurized carbon dioxide and transported.
A carbon dioxide transport method characterized by that. The method for discharging carbon dioxide from the carbon dioxide transport container according to any one of claims 1 to 8.
It comprises a step of discharging carbon dioxide from the inner tube while activating the pressing device to press the inner tube.
A carbon dioxide emission method characterized by that.

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