KR20230126237A - Liquid hydrogen composite storage container - Google Patents

Abstract

The present invention relates to a liquefied hydrogen composite storage container, and more particularly, to recover hydrogen vaporized from a liquefied hydrogen storage container and store it in a vaporized hydrogen tank, and to use and store liquefied hydrogen by simultaneously or selectively using liquefied hydrogen and vaporized hydrogen. An inner tank 100 for storing liquefied hydrogen to improve efficiency and improving the filling efficiency of a liquid hydrogen container; and arranged in a shape surrounding the inner tank 100 from the outside to accommodate the inner tank 100. an outer shell 200; and a vacuum insulator 300 formed in a space where the inner shell 100 and the outer shell 200 are spaced apart from each other to form a predetermined gap between the inner shell 100 and the outer shell 200. and a gas receiving part 400 separately provided outside the outer tub 200 to store gaseous hydrogen generated by vaporizing liquefied hydrogen stored in the inner tub 100; and one end of the inner tub 100 and the A first pipe 510 that communicates with the outer tub 200 and has a selection control means 511 in the middle so that the other end can communicate with the outside of the outer tub 200. One end connects the inner tub 100 and the outer tub 200. The selection control means of the first pipe 510 ( 511) a pipe part 500 provided with a third pipe 530 and a liquefied hydrogen filling pipe 540 communicating with the outside; and a control unit 600 configured to collect operation information of the inner tub 100, the outer tub 200, and the gas receiving unit 400, and is connected to the selection control means 511 to transmit an ON/OFF control signal. It relates to providing a liquefied hydrogen composite storage container comprising;

Description

Liquid hydrogen composite storage container { LIQUID HYDROGEN COMPOSITE STORAGE CONTAINER }

The present invention relates to a liquefied hydrogen composite storage container, and more particularly, to recover hydrogen vaporized from a liquefied hydrogen storage container and store it in a vaporized hydrogen tank, and to use and store liquefied hydrogen by simultaneously or selectively using liquefied hydrogen and vaporized hydrogen. It relates to providing a liquefied hydrogen composite storage container including an inner tank, an outer tank, a vacuum insulation unit, a gas receiving unit, a casing unit, a piping unit, and a control unit to improve efficiency and improve the filling efficiency of the liquefied hydrogen container.

In general, as a way to solve the problems of air pollution and global warming caused by excessive use of fossil fuels, research on using non-hydrocarbon fuels has been actively conducted at home and abroad. Among the various methods proposed to solve this problem, the most efficient and representative method is the use of hydrogen energy.

Unlike hydrocarbon-based energy, hydrogen energy can be classified as a renewable energy source because only water is generated without emission of carbon dioxide during combustion and hydrogen can be obtained from water again.

Hydrogen is widely used as a raw material for chemical products and a process gas for chemical plants, and recently, its demand as a raw material for fuel cells, which is a future energy technology, is increasing. In addition, it is evaluated as the most powerful and only alternative that can solve the problem of rising prices or depletion of fossil fuels and environmental problems that mankind is currently facing.

In order to use hydrogen as an energy source, it must not only be safely stored, but also inexpensive to transport to where it is needed. When hydrogen is stored or transported in a gaseous state, a large amount cannot be stored or transported because of its large volume. Therefore, there is a problem that it is difficult to apply it as an energy source due to cost problems. In order to store and transport hydrogen in large quantities, it is stored or transported after being liquefied.

Therefore, in order to utilize hydrogen as an energy source, a liquid hydrogen storage tank is essential.

It is cryogenic at the liquefaction temperature of liquefied hydrogen, or -253°C. That is, when the temperature inside the tank is -253 ° C or higher, there is a problem that hydrogen is vaporized and the pressure inside the storage tank rises. Therefore, in the case of a liquefied hydrogen storage tank, it must be insulated from the outside to keep the liquefied hydrogen in a liquid state. To this end, the conventional liquefied hydrogen storage tank has a double structure to minimize heat transfer of liquefied hydrogen.

Liquid hydrogen has no choice but to naturally vaporize little by little depending on the insulation performance and temperature change of the storage container, and the pressure increase in the storage container due to vaporization may lead to safety accidents such as explosions.

Therefore, a method of discharging vaporized hydrogen to the outside to prevent an increase in pressure inside the storage container or re-liquefying vaporized hydrogen is used. The method of discharging vaporized hydrogen to the outside is the simplest way to control the pressure, but Vaporized hydrogen leads to total loss, resulting in low storage efficiency and low economic feasibility. The re-liquefaction method requires a separate re-liquefaction system outside the storage container, resulting in high costs and requiring a certain amount of space for the facility. Therefore, it is not suitable to solve the problem inside the storage container.

Patent Publication No. 10-2018-0106682 (published on October 01, 2018) Patent Publication No. 10-2020-0004609 (published on January 14, 2020)

The technical problem to be achieved by the present invention is to solve the above problems or needs, recovering hydrogen vaporized in a liquid hydrogen storage container and storing it in a vaporized hydrogen tank to simultaneously or selectively use liquid hydrogen and vaporized hydrogen It is intended to provide a liquefied hydrogen composite storage container that improves the use and storage efficiency of liquefied hydrogen and at the same time improves the liquefied hydrogen container filling efficiency.

Another object of the present invention is to provide an inner tub 100 for storing liquefied hydrogen, an outer tub 200 disposed in a shape surrounding the inner tub 100 from the outside and provided to accommodate the inner tub 100, and the inner tub ( 100) and the outer tank 200 are spaced apart from each other, and the vacuum insulation part 300 formed in the space forming a predetermined gap between the inner tank 100 and the outer tank 200 is a liquefaction that can stably store liquefied hydrogen. It is intended to provide a hydrogen composite storage container.

Another object of the present invention is to use a gas receiving portion 400 separately provided outside the outer tub 200 to store gaseous hydrogen generated by vaporizing liquefied hydrogen stored in the inner tub 100. It is intended to provide a liquefied hydrogen composite storage container that can use vaporized hydrogen.

Another object of the present invention is to provide a first pipe 510, one end of which is provided to communicate with the inner tub 100 and the outer tub 200 and the other end to communicate with the outside of the outer tub 200, and one end of the inner tub 100 and a second pipe 520 communicated with the outer tub 200 and the other end communicated with the gas accommodating part 400 and one end communicated with the gas accommodating part 400 and the other end communicated with the first pipe 510 ) and the third pipe 530 and the liquefied hydrogen filling pipe 540 communicating with the selection control means 511, the pipe part 500, the inner tank 100, the outer tank 200, and the gas receiving part A liquid hydrogen composite storage container capable of selectively using liquefied or vaporized hydrogen as a control unit 600 provided to collect operation information of 400 and to transmit an ON/OFF control signal by being connected to the selection control means 511 you want to provide

Another object of the present invention is that the liquid hydrogen filling pipe 540 is provided with a filling control valve 541 to control whether or not to fill the liquid hydrogen connected to the control unit 600, and the control unit 600 controls the collected Controlling the filling valve 541 to open when the amount of liquefied hydrogen in the inner tub 100 is less than a predetermined volume % of the total fillable capacity of the inner tub 100 using information on the amount of liquefied hydrogen filled in the inner tub 100 or pressure However, it is intended to provide a liquefied hydrogen composite storage container in which the predetermined capacity % is provided as a positive number so that the liquefied gas can be filled in a state before empty, thereby increasing the liquefied gas filling efficiency.

Another object of the present invention is to allow the control unit 600 of the selection control unit 511 to simultaneously collect collected gas pressure information of the gas container 400 and liquefied hydrogen capacity information of the inner tub 100. provided, and when the internal pressure information of the gas accommodating part 400 collected by the control part 600 is equal to or greater than a predetermined pressure, it is set to be closed by a control signal from the control part 600, and vaporization stored in the gas accommodating part 400 An object of the present invention is to provide a liquefied hydrogen composite storage container provided to be discharged to the outside prior to the liquefied hydrogen stored in the inner tank 100 when the hydrogen is filled to a predetermined pressure or higher.

Another object of the present invention is that the control unit 600, when the collected liquefied hydrogen capacity information of the inner tub 100 is a predetermined amount or more and the collected gas internal pressure information of the gas receiving unit 400 is a predetermined pressure or less, An object of the present invention is to provide a liquefied hydrogen composite storage container in which the liquefied hydrogen stored in the inner tank 100 can be discharged to the outside with priority.

Another object of the present invention is that the liquefied hydrogen filling pipe 540 is provided with a double pipe of an exterior 542 and an inner tube 543, and an insulator 544 is disposed between the exterior 542 and the inner tube 543. , The inner tube 543 is provided with a plurality of flexible tubes 543a to be stretchable and expandable at predetermined intervals to provide a liquefied hydrogen composite storage container that is prevented from being damaged.

Another object of the present invention is a pipe connection in which an accommodation space 710 is formed inside to accommodate the outer tank 100 and the gas accommodation unit 400 therein, and the entrance and exit of the pipe unit 500 are accommodated. A casing part 700 in which the ball 720 is formed is provided, and a casing insulator 730 is disposed on an inner surface of the casing part 700 and is connected to the controller 600 to the outside so that the inner tub 100 and the inner tub 100 are formed. Filling information of the gas receiving unit 400 is displayed, and the control panel 740 includes an input means 741 and an output means 742 to enable input to store control signals or setting information in the controller 600. ) is provided to provide a liquid hydrogen composite storage container that is easy to use and monitor.

On the other hand, the technical problems to be achieved in the present invention are not limited to the above-mentioned technical problems, and other technical problems that are not mentioned will become clear to those skilled in the art from the description below. You will be able to understand.

A liquefied hydrogen composite storage container related to an example of the present invention for realizing the above object may include, first, an inner tank 100 for storing liquefied hydrogen.

In addition, an outer tub 200 disposed in a shape surrounding the inner tub 100 from the outside and provided to accommodate the inner tub 100 may be included.

Here, the vacuum insulator 300 is formed in a space where the inner tub 100 and the outer tub 200 are spaced apart from each other to form a predetermined gap between the inner tub 100 and the outer tub 200; can

Here, a gas accommodating part 400 separately provided outside the outer tub 200 to store gaseous hydrogen generated by vaporizing liquefied hydrogen stored in the inner tub 100; may be included.

In addition, a first pipe 510 having one end communicating with the inner tub 100 and the outer tub 200 and the other end communicating with the outside of the outer tub 200, one end connecting the inner tub 100 and the outer tub 200 , and the other end communicates with the second pipe 520 provided to communicate with the gas accommodating part 400 and one end communicates with the gas accommodating part 400 and the other end communicates with the first pipe 510. A third pipe 530 communicating with the means 511 and a pipe part 500 provided as a liquid hydrogen filling pipe 540; may be included.

In addition, the control unit 600 is provided to collect operation information of the inner tub 100, the outer tub 200, and the gas container 400, and is connected to the selection control means 511 to transmit an ON/OFF control signal. );

Here, the liquefied hydrogen filling pipe 540 is provided with a filling control valve 541 connected to the controller 600 to control whether or not to fill the liquefied hydrogen, and the controller 600 controls whether or not the collected inner tub 100 is filled with liquefied hydrogen. Provided to control the filling valve 541 to open when the amount of liquefied hydrogen in the inner tank 100 is less than a predetermined volume % of the total fillable capacity of the inner tank 100 by using the filled liquefied hydrogen amount or pressure information, and the predetermined volume % may be characterized as being a positive number.

At this time, the selection control means 511 is provided so that the control unit 600 simultaneously collects the collected gas pressure information of the gas receiving unit 400 and the liquefied hydrogen capacity information of the inner tub 100, and the control unit ( 600) is set to be closed by a control signal from the control unit 600 when the internal pressure information of the gas accommodating unit 400 is higher than a predetermined pressure, so that the hydrogen vapor stored in the gas accommodating unit 400 is at a predetermined pressure or higher. When it is filled, it may be characterized in that it is provided to be discharged to the outside prior to liquefied hydrogen stored in the inner tank 100.

Here, the controller 600 controls the internal tub 100 when the collected liquefied hydrogen capacity information of the inner tub 100 is equal to or greater than a predetermined amount and the collected gas internal pressure information of the gas container 400 is equal to or less than a predetermined pressure. It may be characterized in that it is provided to discharge the stored liquefied hydrogen to the outside first.

On the other hand, the liquefied hydrogen filling pipe 540 is provided as a double pipe of an outer pipe 542 and an inner pipe 543, and a heat insulating material 544 is disposed between the outer pipe 542 and the inner pipe 543, and the inner pipe 543 may be characterized in that a plurality of flexible tubes 543a are provided to be stretchable and expandable at predetermined intervals.

At this time, an accommodating space 710 is formed inside to accommodate the outer tank 100 and the gas accommodating part 400 therein, and a pipe connection hole 720 accommodating the inlet and outlet of the pipe part 500 is formed. A casing portion 700 is further provided, wherein a casing insulator 730 is disposed on an inner surface of the casing portion 700 and is connected to the control unit 600 to the outside to form the inner tub 100 and the gas receiving portion 400. ) is displayed, and a control panel 740 including an input means 741 and an output means 742 is provided so that control signals or setting information can be stored in the controller 600. can be characterized.

Accordingly, the present invention provides a liquefied hydrogen composite storage container,

First, the hydrogen vaporized from the liquid hydrogen storage container is recovered and stored in the vaporized hydrogen tank, and the liquid hydrogen and vaporized hydrogen are used simultaneously or selectively to improve the use and storage efficiency of the liquid hydrogen, and at the same time, the effect of improving the liquid hydrogen container filling efficiency. provides

Second, an inner tub 100 for storing liquefied hydrogen, an outer tub 200 disposed in a shape surrounding the inner tub 100 from the outside and provided to accommodate the inner tub 100, and the inner tub 100 and the outer tub The vacuum insulator 300 formed in the space between the inner tub 100 and the outer tub 200 at a predetermined interval by being spaced apart from each other has an effect of stably storing liquefied hydrogen.

Third, using the gas receiving part 400 provided separately outside the outer tub 200 to store gaseous hydrogen generated by vaporizing the liquefied hydrogen stored in the inner tub 100, vaporized hydrogen that is naturally vaporized can be used. can

Fourth, a first pipe 510 having one end communicating with the inner tub 100 and the outer tub 200 and the other end communicating with the outside of the outer tub 200 and one end connecting the inner tub 100 and the outer tub 200 The second pipe 520 communicates with and the other end is provided to communicate with the gas receiving portion 400, and one end communicates with the gas receiving portion 400 and the other end communicates with the first pipe 510 and the selection control means ( 511) Operation of the pipe part 500 provided with the third pipe 530 communicating with the outside and the liquid hydrogen filling pipe 540, the inner tank 100, the outer tank 200, and the gas receiving part 400 There is an effect of selectively using liquefied or vaporized hydrogen as a controller 600 provided to collect information and to transmit an ON/OFF control signal by being connected to the selection control means 511.

Fifth, the liquefied hydrogen filling pipe 540 is provided with a filling control valve 541 connected to the controller 600 to control whether or not to fill the liquefied hydrogen. Provided to control the filling valve 541 to open when the amount of liquefied hydrogen in the inner tank 100 is less than a predetermined volume % of the total fillable capacity of the inner tank 100 by using the filled liquefied hydrogen amount or pressure information, and the predetermined volume % is provided as a positive number so that the liquefied gas can be filled in a state before empty, so that the liquefied gas filling efficiency is high.

Sixth, the control unit 600 of the selection control unit 511 is provided to simultaneously collect the collected information on the internal pressure of the gas of the gas receiving unit 400 and the information on the capacity of liquefied hydrogen in the tub 100, and the control unit ( 600) is set to be closed by a control signal from the control unit 600 when the internal pressure information of the gas accommodating unit 400 is higher than a predetermined pressure, so that the hydrogen vapor stored in the gas accommodating unit 400 is at a predetermined pressure or higher. When it is filled, it may be discharged to the outside prior to liquefied hydrogen stored in the inner tub 100 .

Seventh, when the information on the liquefied hydrogen capacity of the inner tub 100 collected by the control unit 600 is equal to or greater than a predetermined amount and the collected internal pressure information of the gas container 400 is equal to or less than a predetermined pressure, the control unit 600 controls the internal tub 100 Stored liquefied hydrogen can be discharged to the outside with priority.

Eighth, the liquefied hydrogen filling pipe 540 is provided as a double pipe of an outer pipe 542 and an inner pipe 543, and an insulator 544 is disposed between the outer pipe 542 and the inner pipe 543, and the inner pipe 543 A plurality of flexible tubes 543a are provided to be stretchable and expandable at predetermined intervals to prevent breakage.

Ninth, an accommodating space 710 is formed inside to accommodate the outer tub 100 and the gas accommodating portion 400 therein, and a pipe connection hole 720 accommodating the inlet and outlet of the pipe portion 500 is formed. A casing portion 700 is provided, wherein a casing insulator 730 is disposed on an inner surface of the casing portion 700 and is connected to the controller 600 on the outside to form the inner tub 100 and the gas receiving portion 400. The filling information of is displayed, and a control panel 740 including an input means 741 and an output means 742 is provided to enable input to store control signals or setting information in the controller 600, and Monitoring is easy.

On the other hand, the effects obtainable in the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below. You will be able to.

The following drawings attached to this specification illustrate a preferred embodiment of the present invention, and together with the detailed description of the present invention serve to further understand the technical idea of the present invention, the present invention is limited to those described in the drawings. It should not be construed as limiting.
1 to 3 are 3D views for explaining the overall configuration of a liquefied hydrogen composite storage container according to a preferred embodiment of the present invention.
4 and 5 are 3D views for explaining an inner shell, an outer shell, and a vacuum insulator of a liquefied hydrogen composite storage container according to a preferred embodiment of the present invention.
6 is a 3D view for explaining a filling control valve of a liquefied hydrogen composite storage container according to a preferred embodiment of the present invention.
7 is a 3D view for explaining a selection control means of a liquefied hydrogen composite storage container according to a preferred embodiment of the present invention.
8 and 9 are 3D views for explaining the liquefied hydrogen filling pipe of the liquefied hydrogen composite storage container according to a preferred embodiment of the present invention.
10 and 11 are views for explaining a flexible pipe and an insulator of a liquefied hydrogen composite storage container according to a preferred embodiment of the present invention.
12 is a 3D view for explaining a casing of a liquefied hydrogen composite storage container according to a preferred embodiment of the present invention.
13 and 14 are block diagrams for explaining a control unit of a liquefied hydrogen composite storage container according to a preferred embodiment of the present invention.
15 to 18 are conceptual views for explaining a piping operation mode of a liquefied hydrogen composite storage container according to a preferred embodiment of the present invention.

Specific structural or functional descriptions of the embodiments according to the concept of the present invention disclosed in this specification are only illustrated for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention It can be embodied in various forms and is not limited to the embodiments described herein.

Embodiments according to the concept of the present invention can apply various changes and have various forms, so the embodiments are illustrated in the drawings and described in detail in this specification. However, this is not intended to limit the embodiments according to the concept of the present invention to specific disclosure forms, and includes all changes, equivalents, or substitutes included in the spirit and technical scope of the present invention.

1 to 3 are 3D views for explaining the overall configuration of a liquefied hydrogen composite storage container according to a preferred embodiment of the present invention, and FIGS. 4 and 5 are liquefied hydrogen composite storage containers according to a preferred embodiment of the present invention. It is a 3D drawing for explaining the inner tank, the outer tank and the vacuum insulation part, and FIG. 6 is a 3D drawing for explaining the filling control valve of the liquefied hydrogen composite storage container according to a preferred embodiment of the present invention. It is a 3D drawing for explaining the selection control means of the liquefied hydrogen composite storage container according to an embodiment, and FIGS. 8 and 9 are for explaining the liquefied hydrogen filling pipe of the liquefied hydrogen composite storage container according to a preferred embodiment of the present invention. It is a 3D drawing, and FIGS. 10 and 11 are views for explaining a flexible pipe and an insulator of a liquefied hydrogen composite storage container according to a preferred embodiment of the present invention.

12 is a 3D drawing for explaining the casing of the liquefied hydrogen composite storage container according to a preferred embodiment of the present invention, and FIGS. 13 and 14 illustrate the control section of the liquefied hydrogen composite storage container according to a preferred embodiment of the present invention. 15 to 18 are conceptual diagrams for explaining a piping operation mode of a liquefied hydrogen composite storage container according to a preferred embodiment of the present invention.

The liquefied hydrogen composite storage container according to an embodiment of the present invention recovers the hydrogen vaporized in the liquefied hydrogen storage container, stores it in a vaporized hydrogen tank, and first stores the liquefied hydrogen so that the liquefied hydrogen and vaporized hydrogen can be used simultaneously or selectively. The inner tub 100 is configured. The inner tub 100 is made of a metal material having a circular cross section so as to have high resistance to pressure, and is disposed in a shape surrounding the inner tub 100 from the outside to accommodate the inner tub 100. The outer tub 200 is provided so that the outer tub 200 is also preferably made of a metal material having a circular cross section to correspond to the size and shape of the inner tub 100.

At this time, the inner tub 100 and the outer tub 200 are spaced apart from each other to form a vacuum insulator 300 formed in a space forming a predetermined interval between the inner tub 100 and the outer tub 200. As for the pressure and heat insulation member, a vacuum pressure and heat insulation member used in a normal liquefied hydrogen container are used.

Meanwhile, a gas receiving unit 400 is separately included outside the outer tub 200 to store gaseous hydrogen generated by vaporizing liquefied hydrogen stored in the inner tub 100, and a vaporizing device in the inner tub 200. It is provided to collect and store gaseous hydrogen that is naturally vaporized without the need, and the gas receiving part 400 is also made of a metal material and has a circular cross section and is configured to have resistance to pressure.

At this time, a first pipe 510 having one end communicating with the inner tub 100 and the outer tub 200 and the other end communicating with the outside of the outer tub 200, and one end connecting the inner tub 100 and the outer tub 200 , and the other end communicates with the second pipe 520 provided to communicate with the gas accommodating part 400 and one end communicates with the gas accommodating part 400 and the other end communicates with the first pipe 510. The pipe part 500 provided as the third pipe 530 and the liquid hydrogen filling pipe 540 communicating with the means 511 is opened and closed so that the liquid hydrogen gas or vaporized hydrogen gas is selectively used, respectively. 500 may be configured with a pressure control valve.

In addition, the control unit 600 collects operation information of the inner tub 100, the outer tub 200, and the gas container 400 and is connected to the selection control means 511 to transmit an ON/OFF control signal. that is composed

At this time, the control unit 600 may be connected to a smart device or a management server through a network.

Here, the liquefied hydrogen filling pipe 540 is provided with a filling control valve 541 connected to the controller 600 to control whether or not to fill the liquefied hydrogen, and the controller 600 controls whether or not the collected inner tub 100 is filled with liquefied hydrogen. Provided to control the filling valve 541 to open when the amount of liquefied hydrogen in the inner tank 100 is less than a predetermined volume % of the total fillable capacity of the inner tank 100 by using the filled liquefied hydrogen amount or pressure information, and the predetermined volume % is composed of a positive number greater than zero, so that the inner tank 200 is completely empty and the temperature is reduced to a required temperature during filling, and energy inefficiency generated is compensated in advance.

At this time, the selection control means 511 is provided so that the control unit 600 simultaneously collects the collected gas internal pressure information of the gas receiving unit 400 and the liquefied hydrogen capacity information of the inner tub 100, and the control unit ( 600) is set to be closed by a control signal from the controller 600 when the internal pressure information of the gas accommodating part 400 is higher than a predetermined pressure, and the hydrogen vapor stored in the gas accommodating part 400 is set to a predetermined pressure or higher. When it is filled, it is provided to be discharged to the outside prior to the liquefied hydrogen stored in the inner tub 100, or the control unit 600 determines that the collected liquefied hydrogen capacity information of the inner tub 100 is a predetermined amount or more and the collected gas When the gas internal pressure information of the accommodating part 400 is equal to or less than a predetermined pressure, the liquid hydrogen stored in the inner tub 100 is discharged to the outside with priority.

At this time, the control unit 600 may be provided to determine the discharge mode by using information on the difference between the internal pressures of the inner tub 100 and the gas receiving unit 400 .

On the other hand, the liquefied hydrogen filling pipe 540 is provided as a double pipe of an outer pipe 542 and an inner pipe 543, and a heat insulating material 544 is disposed between the outer pipe 542 and the inner pipe 543, and the inner pipe 543 A plurality of flexible tubes 543a are provided to be stretchable and expandable at predetermined intervals, and the inner tube 543 compresses and expands according to the temperature of liquefied hydrogen to prevent the inner tube 543 or the exterior 542 from being damaged It is desirable to be able to do so.

Here, the flexible tube 543a is formed in a sawtooth or wavy shape and is preferably arranged at predetermined intervals in parts of the entire inner tube 530.

At this time, an accommodating space 710 is formed inside to accommodate the outer tank 100 and the gas accommodating part 400 therein, and a pipe connection hole 720 accommodating the inlet and outlet of the pipe part 500 is formed. A casing portion 700 is further provided, wherein a casing insulator 730 is disposed on an inner surface of the casing portion 700 and is connected to the control unit 600 to the outside to form the inner tub 100 and the gas receiving portion 400. ) is displayed, and a control panel 740 including an input means 741 and an output means 742 is provided so that control signals or setting information can be stored in the controller 600. Preferably, the input unit 741 and the output unit 742 are connected to the above-described smart device or management server through a network to be configured in the smart device or management server.

Using the liquefied hydrogen composite storage container according to an embodiment of the present invention described above, hydrogen vaporized in the liquefied hydrogen storage container is recovered, stored in a vaporized hydrogen tank, and liquefied by simultaneously or selectively using liquefied hydrogen and vaporized hydrogen. The use and storage efficiency of hydrogen is improved, and the liquid hydrogen container filling efficiency is improved at the same time. The outer tub 200 provided to allow the inner tub 100 and the outer tub 200 to be spaced apart from each other and formed in a space forming a predetermined gap between the inner tub 100 and the outer tub 200 ( 300) to stably store liquefied hydrogen, and a gas receiving portion 400 provided separately outside the outer tub 200 to store gaseous hydrogen generated by vaporization of the liquefied hydrogen stored in the inner tub 100 Vaporized hydrogen that is naturally vaporized can be used, and a selection control means 511 is provided in the middle so that one end communicates with the inner tub 100 and the outer tub 200 and the other end communicates with the outside of the outer tub 200. A first pipe 510 having one end in communication with the inner tub 100 and the outer tub 200 and the other end in communication with the gas accommodating part 400 and a second pipe 520 having one end in communication with the gas accommodating part 400, and the other end is provided with a third pipe 530 and a liquefied hydrogen filling pipe 540 communicating with the outside of the selection control means 511 of the first pipe 510, and To the control unit 600 provided to collect operation information of the inner tub 100, the outer tub 200, and the gas receiving unit 400, and is connected to the selection control means 511 to transmit an ON/OFF control signal. The effect of selectively using liquefied or vaporized hydrogen is expected, and the liquefied hydrogen filling pipe 540 is provided with a filling control valve 541 to control whether or not to fill the liquefied hydrogen connected to the controller 600, The controller 600 controls the filling valve 541 when the amount of liquefied hydrogen in the inner tub 100 is less than a predetermined volume % of the total refillable capacity of the inner tub 100 using the collected information on the amount or pressure of liquefied hydrogen filled in the inner tub 100. ) is provided to control the opening, but the predetermined capacity % is provided so that the liquefied gas can be filled in a state greater than zero, so that energy waste due to the liquefied gas filling is improved, and the selection control means 511 is the control unit ( 600) is provided to simultaneously collect the collected gas internal pressure information of the gas accommodating part 400 and the liquefied hydrogen capacity information of the inner tub 100, When the internal pressure information is higher than a predetermined pressure, it is set to be closed by a control signal from the control unit 600, and when the vaporized hydrogen stored in the gas receiving unit 400 is filled to a higher pressure than a predetermined pressure, the liquefied hydrogen stored in the inner tub 100 Priority may be given to discharge to the outside, and the information on the liquefied hydrogen capacity of the inner tank 100 collected by the control unit 600 is a predetermined amount or more and the collected gas internal pressure information of the gas receiving unit 400 is a predetermined pressure or less. In this case, the liquefied hydrogen stored in the inner tank 100 may be discharged to the outside with priority. A heat insulating material 544 is disposed between the inner tube 543, and the inner tube 543 is provided with a plurality of flexible tubes 543a that can be stretched and expanded at predetermined intervals to prevent damage, and to prevent damage to the outer shell 100 and the An accommodation space 710 is formed inside to accommodate the gas accommodation unit 400 therein, and a casing unit 700 is provided with a pipe connection hole 720 for receiving the inlet and outlet of the pipe unit 500. A casing insulator 730 is disposed on the inner surface of the casing part 700 and is connected to the control part 600 on the outside so that filling information of the inner tub 100 and the gas receiving part 400 is displayed, and the control part With the control panel 740 including an input means 741 and an output means 742 capable of being input to store control signals or setting information in the 600, effects of simple use and monitoring are expected.

The present invention has been described above through a preferred embodiment, but the above-described embodiment is only an illustrative description of the technical idea of the present invention, and various changes are possible within the scope of not departing from the technical idea of the present invention. Those with ordinary knowledge will be able to understand. Therefore, the protection scope of the present invention should be construed by the matters described in the claims, not by the specific examples, and all technical ideas within the corresponding scope should be construed as being included in the scope of the present invention.

100 ... domestic help
200 ... foreign aid
300 ... vacuum insulation
400 ... gas receiving part
500 ... piping
510 ... 1st pipe
511 ... selection control means
520 ... 2nd pipe
530 ... 3rd pipe
540 ... Liquefied hydrogen filling pipe
541 ... filling control valve
542 ... Appearance
543 ... Inner tube
543a ... flexible pipe
544 ... Insulation
600 ... control unit
700 ... casing part
710 ... accommodation space
720 ... plumber
730 ... casing insulation
740 ... control panel
741 ... input means
742 ... output means

Claims (6)

an inner tank 100 for storing liquid hydrogen;
an outer tub 200 disposed in a shape surrounding the inner tub 100 from the outside and provided to accommodate the inner tub 100;
a vacuum insulator 300 formed in a space where the inner tub 100 and the outer tub 200 are spaced apart from each other to form a predetermined gap between the inner tub 100 and the outer tub 200;
a gas accommodating part 400 separately provided outside the outer tub 200 to store gaseous hydrogen generated by vaporizing liquefied hydrogen stored in the inner tub 100;
A first pipe 510 having one end communicating with the inner tub 100 and the outer tub 200 and the other end communicating with the outside of the outer tub 200, one end communicating with the inner tub 100 and the outer tub 200 And the other end communicates with the second pipe 520 provided to communicate with the gas receiving portion 400 and one end communicates with the gas receiving portion 400 and the other end communicates with the first pipe 510 (selection control means ( 511) is provided with a third pipe 530 and a liquefied hydrogen filling pipe 540 communicating with the pipe portion 500; and
a control unit 600 provided to collect operation information of the inner tub 100, the outer tub 200, and the gas container 400, and is connected to the selection control means 511 to transmit an ON/OFF control signal; including,
Liquid hydrogen composite storage container.
According to claim 1,
A filling control valve 541 is provided in the liquefied hydrogen filling pipe 540 to control whether liquefied hydrogen is filled, which is connected to the controller 600,
The controller 600,
The filling valve 541 can be opened when the amount of liquefied hydrogen in the inner tub 100 is less than a predetermined volume % of the total fillable capacity of the inner tub 100 using the collected information on the amount or pressure of liquefied hydrogen filled in the inner tub 100. It is provided to control, characterized in that the predetermined capacity % is a positive number greater than zero,
Liquid hydrogen composite storage container.
According to claim 2,
The selection control means 511,
The control unit 600 is provided to simultaneously collect the collected gas pressure information of the gas receiving unit 400 and liquid hydrogen capacity information of the inner tub 100,
When the internal pressure information of the gas accommodating part 400 collected by the controller 600 is equal to or greater than a predetermined pressure, it is set to be closed by a control signal from the controller 600, and the hydrogen vapor stored in the gas accommodating part 400 is set to a predetermined pressure. Characterized in that it is provided to be discharged to the outside prior to the liquefied hydrogen stored in the inner tank 100 when the pressure is filled or higher.
Liquid hydrogen composite storage container.
According to claim 3,
The controller 600,
When the collected liquefied hydrogen capacity information of the inner tub 100 is equal to or greater than a predetermined amount and the collected gas internal pressure information of the gas container 400 is equal to or less than a predetermined pressure, the liquefied hydrogen stored in the inner tub 100 is given priority to the outside. Characterized in that it is provided to be discharged,
Liquid hydrogen composite storage container.
According to claim 2,
The liquefied hydrogen filling pipe 540 is provided as a double pipe of an exterior 542 and an inner tube 543, and an insulator 544 is disposed between the exterior 542 and the inner tube 543,
The inner tube 543 is characterized in that a plurality of flexible tubes 543a are provided to be stretchable and expandable at predetermined intervals,
Liquid hydrogen composite storage container.
According to claim 4,
A casing in which an accommodating space 710 is formed inside to accommodate the outer tank 100 and the gas accommodating portion 400 therein, and a pipe connection hole 720 accommodating the inlet and outlet of the pipe portion 500 is formed. The unit 700 is further provided,
A casing insulator 730 is disposed on the inner surface of the casing part 700 and is connected to the control part 600 on the outside so that filling information of the inner tub 100 and the gas receiving part 400 is displayed, and the control part ( 600) is characterized in that a control panel 740 including an input means 741 and an output means 742 capable of being input to store control signals or setting information is provided,
Liquid hydrogen composite storage container.