KR102568581B1 - Storage tank for liquefied hydrogen - Google Patents

Abstract

The present invention relates to a liquefied hydrogen storage tank, and more particularly, to a liquefied hydrogen storage tank capable of efficiently vacuuming a vacuum layer formed between an inner tank and an outer tank.
A liquefied hydrogen storage tank according to the present invention includes an inner tank, an outer tank, an insulator, and a bulkhead means. The inner tank stores liquefied hydrogen therein. The outer tank is spaced apart from the inner tank at a predetermined interval to accommodate the inner tank so that a vacuum layer can be formed between the outer tank and the inner tank. The insulating material is filled in the vacuum layer. The bulkhead means is made of a flexible material and has one end coupled to the inner tank and the other end coupled to the outer tank to separate the vacuum layer into a plurality of vacuum chambers.
According to the present invention, the vacuum layer in the storage tank is separated into a plurality of vacuum chambers. Therefore, since each vacuum chamber can be evacuated to make the entire vacuum layer into a vacuum, the formation of the vacuum layer can be facilitated.
also. According to the present invention, the vacuum layer is formed of a plurality of separate vacuum chambers. Therefore, even if the vacuum of one vacuum chamber is destroyed, the vacuum of the other vacuum chamber can be maintained, so that the vacuum of the entire vacuum chamber can be prevented from being destroyed.

Description

Storage tank for liquefied hydrogen}

The present invention relates to a liquefied hydrogen storage tank, and more particularly, to a liquefied hydrogen storage tank capable of efficiently vacuuming a vacuum layer formed between an inner tank and an outer tank.

Recently, the demand for eco-friendly energy is continuously increasing due to the depletion of fossil fuels and environmental problems. Hydrogen not only exists in abundance on earth, but can also be used as an energy source and is regarded as a next-generation alternative energy source because it does not emit pollutants at all.

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 liquefied hydrogen storage tank is essential.

The liquefaction temperature of liquefied hydrogen is -253℃, which is extremely low. So, 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.

Registered Patent No. 10-2039573 (registration date 2019.10.28)

In the case of a liquefied hydrogen storage tank, it is composed of a double structure in which a vacuum layer is formed for insulation. That is, it consists of an inner tank and an outer tank that surrounds the inner tank at a predetermined interval so that a vacuum layer is formed, and liquefied hydrogen is stored in the inner tank. A heat insulating material is inserted into the vacuum layer. At this time, when the storage tank is formed with a large capacity, there is a problem that it is difficult to form a vacuum between the inner tank and the outer tank because the volume of the vacuum layer is large.

The present invention is to solve the above problems. An object of the present invention is to provide a liquefied hydrogen storage tank capable of efficiently vacuuming the vacuum layer.

A liquefied hydrogen storage tank according to the present invention includes an inner tank, an outer tank, an insulator, and a bulkhead means. The inner tank stores liquefied hydrogen therein. The outer tank is spaced apart from the inner tank at a predetermined interval to accommodate the inner tank so that a vacuum layer can be formed between the outer tank and the inner tank. The insulating material is filled in the vacuum layer. The bulkhead means is made of a flexible material and has one end coupled to the inner tank and the other end coupled to the outer tank to separate the vacuum layer into a plurality of vacuum chambers.

In addition, in the liquefied hydrogen storage tank, it is preferable to further include a plurality of filling nozzles and a plurality of vacuum nozzles. The filling nozzle is mounted on an external tank constituting each of the vacuum chambers so as to fill the insulator in each of the vacuum chambers. The vacuum nozzle is mounted on an external tank constituting each of the vacuum chambers so as to vacuum each of the vacuum chambers.

In addition, in the liquefied hydrogen storage tank, the heat insulating material is preferably filled in the vacuum chamber to support the flexible material when the vacuum chamber is in a vacuum state.

According to the present invention, the vacuum layer in the storage tank is separated into a plurality of vacuum chambers. Therefore, since each vacuum chamber can be evacuated to make the entire vacuum layer into a vacuum, the formation of the vacuum layer can be facilitated.

also. According to the present invention, the vacuum layer is formed of a plurality of separate vacuum chambers. Therefore, even if the vacuum of one vacuum chamber is destroyed, the vacuum of the other vacuum chamber can be maintained, so that the vacuum of the entire vacuum chamber can be prevented from being destroyed.

1 is a cross-sectional view of an embodiment of a liquefied hydrogen storage tank according to the present invention;
Figure 2 is a plan sectional view and an enlarged view of part A of the embodiment shown in Figure 1,
3 is a perspective conceptual view of an external tank of the embodiment shown in FIG. 1;

An embodiment of a liquefied hydrogen storage tank according to the present invention will be described with reference to FIGS. 1 to 3 .

The liquefied hydrogen storage tank according to the present invention includes an inner tank 10, an outer tank 20, an insulator 30, a bulkhead means 40, a filling nozzle 50, and a vacuum nozzle 60. do.

The inner tank 10 stores liquefied hydrogen therein. The liquefaction temperature of liquefied hydrogen is -253℃, which is extremely low. That is, when the temperature of the inner tank 10 is higher than -253 ° C, the liquefied hydrogen is vaporized and the pressure of the inner tank 10 rises. In this case, vaporized hydrogen must be released, which results in a loss of hydrogen. Therefore, insulation of the inner tank 10 is important.

The outer tank 20 is exposed to the atmosphere and serves to prevent the inner tank 10 from being exposed to the outside for insulation of the inner tank 10 . To this end, the outer tank 20 is spaced apart from the inner tank 10 by a predetermined interval to accommodate the inner tank 10 . At this time, a vacuum layer having a vacuum pressure lower than atmospheric pressure is formed in a space between the inner tank 10 and the outer tank 20 spaced apart by a predetermined interval.

The insulator 30 serves to reduce heat transfer to the inner tank 10 . To this end, the heat insulating material 30 is filled in the space between the inner tank 10 and the outer tank 20 . At this time, the insulator 30 may be formed of perlite or glass microspheres.

The bulkhead means 40 serves to separate the vacuum layer between the inner tank 10 and the outer tank 20 into a plurality of vacuum chambers R. That is, since the partition wall means 40 is difficult to form a vacuum in the case of a vacuum layer because it is too large in volume, the vacuum layer is separated into a vacuum chamber R of a size that is easy to vacuum. To this end, a plurality of bulkhead means 40 are provided with a first support bar 41, a second support bar 43, and a flexible material 45, and are mounted between the inner tank 10 and the outer tank 20. do.

One end of the first support bar 41 is coupled to the outer circumferential surface of the inner tank 10 . At this time, a plurality of first support bars 41 are coupled to the outer circumferential surface of the inner tank 10 at a predetermined interval.

One end of the second support bar 43 is coupled to the inner circumferential surface of the outer tank 20 . At this time, a plurality of second support bars 43 are coupled to the inner circumferential surface of the external tank 20 at a predetermined interval.

The flexible material 45 has one end coupled to the end of the first support bar 41 and the other end coupled to the end of the second support bar 43 . In this case, the flexible material 45 may be formed of a fluoropolymer or a silicone rubber sheet. In this embodiment, the flexible material 45 is composed of one sheet of fluoropolymer or silicone rubber sheet, or two sheets are laminated to form the first support bar 41 and the second support bar 43 ) is bonded with an adhesive.

The filling nozzle 50 serves to fill the insulator 30 in each vacuum chamber R. To this end, a plurality of filling nozzles 50 are mounted on the outer circumferential surface of the external tank 20 . Since each vacuum chamber (R) must be filled with a heat insulating material 30, the filling nozzle 50 is mounted on the outer circumferential surface of the external tank 20 constituting each vacuum chamber (R), and the insulating material is attached to each vacuum chamber (R). (30) is formed to be filled.

The vacuum nozzle 60 serves to vacuum each vacuum chamber R. To this end, a plurality of vacuum nozzles 60 are mounted on the external tank 20 . Since each vacuum chamber (R) must have a vacuum layer, the vacuum nozzle 60 is mounted on the external tank 20 constituting each vacuum chamber (R) and applies negative pressure to each vacuum chamber (R) to form a vacuum layer. is formed to form

In this embodiment, the first support bar 41 is coupled to the outer circumferential surface of the inner tank 10, the second support bar 43 is coupled to the inner circumferential surface of the outer tank 20, and the flexible material 45 is once It is coupled to the first support bar 41 and the other end is coupled to the second support bar 43. After the insulator 30 is filled in each vacuum chamber R through the filling nozzle 50, negative pressure is applied to each vacuum chamber R through the vacuum nozzle 60 to remove air as much as possible. Here, when a vacuum is obtained after depressurizing one of the vacuum chambers (R), the other vacuum chambers (R) may be decompressed and vacuumed in turn. At this time, when depressurizing any one vacuum room (R), the flexible material 45 constituting the partition wall may be deformed due to the negative pressure, but the insulation material 30 filled inside supports the flexible material 45 and is damaged prevents it from So the vacuum room (R) can be made into a vacuum. Since all the vacuum chambers R can be made into a vacuum by this operation, the vacuum layer can be effectively formed. also. In the case of this embodiment, the vacuum layer is formed of a plurality of separate vacuum chambers (R). Therefore, even if the vacuum of one vacuum chamber R is destroyed, the vacuum of the other vacuum chamber R can be maintained, so that the vacuum of the entire vacuum chamber can be prevented from being destroyed. Therefore, in the case of the present embodiment, even if the volume of the vacuum layer is large, since the vacuum layer is formed by separating into several vacuum chambers R, the formation of the vacuum layer can be facilitated, so that the insulation of the storage tank can be effectively implemented.

10: inner tank 20: outer tank
30: insulation material 40: bulkhead means
41: first support bar 43: second support bar
45: flexible material 50: filling nozzle
60: vacuum nozzle R: vacuum chamber

Claims (3)

An inner tank for storing liquefied hydrogen therein;
an outer tank spaced apart from the inner tank at a predetermined interval so as to form a vacuum layer between the inner tank and accommodating the inner tank;
A bulkhead means made of a flexible material and having one end coupled to the inner tank and the other end coupled to the outer tank to separate the vacuum layer into a plurality of vacuum chambers;
Insulation materials separately filled in each of the vacuum chambers;
A plurality of filling nozzles mounted on an outer circumferential surface of an external tank constituting each of the vacuum chambers so as to fill each of the vacuum chambers with the heat insulating material;
A liquefied hydrogen storage tank comprising a plurality of vacuum nozzles mounted on an external tank constituting each of the vacuum chambers so as to vacuum each of the vacuum chambers. According to claim 1,
The insulating material is a liquefied hydrogen storage tank, characterized in that filled in the vacuum chamber to support the flexible material when the vacuum chamber is in a vacuum state. delete