KR100907835B1 - Cryogenic Container - Google Patents

Abstract

The present invention relates to a cryogenic container, more specifically, one side is open, the receiving portion is formed in the receiving space therein, and one side is open, is connected to seal the receiving portion, the open side of the receiving portion A cover part formed with injection and discharge holes penetrating to the other side opposite to each other, a guide part installed inside the cover part to seal one open side of the cover part, and having a hole through which one side penetrates, and a hole formed in the guide part A safety valve having a hole through which one side is formed, a spring member elastically supporting the safety valve, and an upper portion of the cover part, connected to the injection hole, and the contents contained in the accommodation part. It is composed of an injection unit for injecting, the safety valve is characterized in that the lifting in accordance with the pressure of the receiving space of the receiving portion.

According to the present invention, the discharge pipe and the safety valve for discharging the contents of the accommodating unit is formed integrally to reduce the manufacturing cost, to form a space for raising the low-temperature contents discharged to the safety valve to be able to discharge the contents more safely. The installation of the pressure guide portion in the receiving portion can prevent the malfunction of the pressing portion.

Cryogenic container, liquid nitrogen, low temperature container, safety valve

Description

Cryogenic Container {VESSEL FOR CONTAING EXTREMELY LOW TEMPERATURE MATERIAL}

The present invention relates to a cryogenic container, and more particularly, by manufacturing a safety valve for maintaining a constant pressure inside the discharge pipe and the accommodation portion for discharging the contents of the accommodation portion, reducing the manufacturing cost of the cryogenic vessel, safety By forming a space between the valve and the discharge groove, when the low-temperature contents are discharged, the contents are heated up to discharge the contents more safely, and the pressure guide portion is installed in the receiving portion to prevent malfunction of the pressing portion, and It relates to a cryogenic container to prevent.

In general, cryogenic containers carry liquid gas, liquid nitrogen, liquid argon, liquid carbon dioxide, and liquid nitrous oxide gas, which are liquefied gases, in a liquid state, and vaporize them with a built-in vaporizer or a separately installed vaporizer. It is used to feed at pressure, temperature and flow rate.

Cryogenic container is a container for filling a liquefied gas with a critical temperature below -50 ℃ at high pressure, and a filled liquefied gas is very low temperature below -150 ℃, so according to the High Pressure Gas Safety Management Act, a cryogenic container is used for In order to prevent an increase in the pressure of the container, heat insulation should be carried out to reduce the heat penetration rate below the prescribed value, and the container material should be made of austenitic stainless steel or aluminum alloy which does not cause low temperature embrittlement.

The conventional cryogenic vessel has a dual structure in which an inner bath made of austenitic stainless steel is installed in an inner space of an outer tank made of carbon steel or the like, and a support material of a material having low thermal conductivity and high strength is formed in the inner tank head of the upper end of the inner tank. It has a structure fixed to the top of the.

Insulation method of super insulation is applied to the space of outer tank and inner tank, which is made of silver foil as a reflection material and special insulation paper as a shielding material, which is wound around the outer surface of the inner tank and formed into a space by high vacuum to insulate the space. to be.

In general, gases having low boiling points, such as natural gas, nitrogen, oxygen, carbon dioxide, hydrogen, argon, helium, and neon, are converted to a liquid state below -150 ° C.

The container for storing the cryogenic liquid needs to be kept at a low temperature in order to keep the stored fluid in a liquid state. Therefore, the container for storing the cryogenic liquid is formed of a double wall that can maintain a vacuum in both an empty state and a filled state. It will effectively prevent heat intrusion.

However, even if the cryogenic liquid is stored in the cryogenic container having a double wall structure in a vacuum state, the cryogenic liquid is not partially provided due to the heat generated by friction with the cryogenic container surface due to the shaking of the cryogenic liquid. As it vaporizes, it is converted to gaseous state.

Therefore, the conventional cryogenic container is to be converted to a gas in a state where the cryogenic liquid is full to increase the internal pressure.

In other words, when the cryogenic container is filled with the cryogenic liquid in the liquid state, as time passes, the gas is converted into a gaseous state as a part of the gas is evaporated. There is a problem inherent in the risk of being broken.

In order to solve the above problems, in the case of the conventional cryogenic container, a safety valve is installed to maintain a constant pressure inside the cryogenic container in order to protect the cryogenic container from the external environment or external shock.

When the pressure inside the cryogenic container rises due to the external environment or external shock, the safety valve of the cryogenic container is operated by the pressure inside the cryogenic container and the pressure inside the cryogenic container is kept constant by discharging the internal contents. Keep it.

Conventional cryogenic vessel is formed separately to the discharge pipe for injecting the contents and the safety valve for maintaining a constant pressure inside the cryogenic vessel, the contents discharged by the safety valve is immediately discharged to the outside of the cryogenic vessel.

The prior art has a problem in that the manufacturing cost increases and the manufacturing process is complicated because each of the discharge pipe for injecting the contents of the cryogenic container and the safety valve for maintaining a constant pressure inside the cryogenic container are formed.

In addition, the conventional safety valve, when discharging the contents for the pressure control inside the cryogenic vessel, immediately discharged to the outside of the cryogenic vessel, there was a problem that the low temperature contents are discharged to damage the user or external equipment, etc. .

The present invention is proposed to solve the above problems.

The present invention is to solve the problems of the prior art made as described above, the cryogenic container according to the present invention is open on one side, the receiving portion is formed in the receiving space therein, and one side is open, sealing the receiving portion A cover part having a spraying hole and a discharge hole penetrating the other side opposite to the open one side of the receiving part, and installed inside the cover part to seal the open one side of the cover part, and a hole through which one side penetrates. A guide valve formed to seal the hole formed in the guide part, the safety valve having a hole through which one side is formed, a spring member elastically supporting the safety valve, and an upper part of the cover part. It is connected to the thread hole, and composed of an injection unit for injecting the contents contained in the receiving portion, the safety valve is the receiving portion Characterized in that the lift according to the space for pressure.

In addition, a space may be formed between the inner surface of the cover portion and the upper surface of the guide portion.

In addition, the injection unit, one end may be composed of a discharge pipe connected to the injection hole formed in the cover portion, one side of the injection nozzle is connected to the discharge pipe, and one side is connected to the discharge pipe to control the injection.

In addition, both sides are open, the space is formed therein, and further includes a pressure guide portion provided to surround the outer surface of the receiving portion, the pressure guide portion is formed by protruding part of the outer surface of the pressure guide portion, Negative pressure can be prevented.

The cryogenic container according to the present invention has an effect of reducing the manufacturing cost and shortening the manufacturing process because the cryogenic container is manufactured integrally with a discharge pipe for injecting the contents of the cryogenic container and a safety valve that maintains a constant pressure inside the cryogenic container.

In addition, when discharging the contents to control the pressure inside the cryogenic vessel, a space is formed between the pressure valve of the cryogenic vessel and the discharge groove, and then the temperature of the discharging contents is lowered and then discharged. There is an effect to reduce.

In addition, there is an effect that can reduce the malfunction of the pressurizing portion for spraying the contents of the cryogenic container by forming a pressure guide portion in the cryogenic container.

Hereinafter, an exemplary cryogenic container according to the present invention will be described in detail with reference to the accompanying drawings.

Cryogenic container according to the present invention, as shown in Figure 2 and 5, the receiving portion 200, the receiving space formed therein, the safety cap 100 is connected to seal the receiving portion 200, It is formed in the upper portion of the safety cap 100 and consists of an injection unit 300 for injecting the contents contained in the receiving portion 200.

1 to 7, the upper portion of the receiving portion 200 is open and the lower portion is formed in a closed cylindrical shape, the receiving space is provided therein, a pedestal for supporting the receiving portion 200 in the lower portion Is formed.

The perimeter of the upper portion of the accommodating part 200 is formed smaller than the perimeter of the lower part of the accommodating part 200 for installation of the pressure guide part 210 which will be described later.

The upper end of the receiving portion 200 is formed in a hollow cylindrical shape, the connection portion 150 is formed with a screw thread on the outer surface for connection with the cover portion 110 is connected.

The safety cap 100 includes a cover part 110 connected to seal the receiving part 200, a guide part 130 installed to seal the cover part 110, and formed with a through hole therein; It consists of a safety valve 140 is installed to seal the ball formed in the guide portion 130, and a spring member 120 provided between the safety valve 140 and the cover 110.

Cover portion 110 is formed in a cylindrical shape of one side is open (┌┐), the injection hole 180 and the discharge hole 160 penetrating the upper surface of the cover portion 110 is formed, respectively.

Threads corresponding to the threads formed on the outer surface of the connection part 150 are formed at the lower end of the inner side of the cover part 110 to connect the cover part 110 and the connection part 150.

The guide part 130 is formed in a plate shape and is installed inside the cover part 110 to seal and divide the space inside the cover part 110, and a ball penetrating to one side is formed.

The bottom circumference of the ball penetrating the guide portion 130 is formed smaller than the upper circumference of the ball penetrating the guide portion 130 is formed radially from the bottom of the ball to the top.

The safety valve 140 is formed in a conical shape, is formed in a size corresponding to the size of the ball formed in the guide portion 130, a ball penetrating one side is formed, the spring member 120 on the upper surface of the safety valve 140 ) Is formed a groove for seating.

Safety valve 140 is installed is inserted into the ball formed in the guide portion 130 to seal the ball formed in the guide portion 130.

One side of the spring member 120 is connected to a groove formed in the upper surface of the safety valve 140 to connect the spring member 120, and the other side of the cover member is opposite to the one side connected to the upper surface of the safety valve 140. Is connected to the inside, the safety valve 140 is elastically supported by the lifting and lowering of the safety valve 140 is possible.

The injection part 300 is connected to the upper surface of the cover part 110 and is formed of a discharge pipe 310, an injection nozzle 320, and a pressurizing part 330.

Discharge pipe 310 is formed in the form of a pipe (pipe) closed one side, the ball is formed to penetrate to one side so that the injection nozzle 320 is inserted, the opening and closing connection portion 350 of the pressing unit 330 on one side is closed A ball to be inserted is provided, and an open side of the discharge pipe 310 is connected to seal the injection hole 180 of the cover 110.

The injection nozzle 320 is formed in the shape of a pipe closed on one side, is inserted into the ball formed in the discharge pipe 310, the ball is formed through the upper surface of the portion inserted into the discharge pipe 310 is discharge pipe 310 And the injection nozzle 320 are formed to communicate with each other.

The pressing unit 330 is connected to the upper end of the discharge pipe 310, is formed in a shape that is bent downward, the opening and closing connection 350 is connected to the lower surface of the portion connecting the pressing unit 330 and the discharge pipe 310 is Inserted into a ball formed on the closed side of the discharge pipe 310, the elastic member 340 is formed between the opening and closing connection portion 350 and the closed one side of the discharge pipe 310, the pressing portion of the opening and closing connection 350 The opening and closing part 360 is formed on the other side opposite to one side connected to the 330, and a ball into which the injection nozzle 320 is inserted is formed on one side of the pressing part 330.

Opening and closing portion 360 is installed to seal the ball formed on the upper surface of the injection nozzle 320, when pressing the pressure unit 330 to open the ball formed on the upper surface of the injection nozzle 320 to inject the contents, When the pressurization is stopped, the injection is stopped by closing the ball formed on the upper surface of the injection nozzle 320 by the elastic member 340.

The pressing guide portion 210 is formed in a hollow cylindrical shape formed inside the same as the circumference of the upper portion of the receiving portion 200, the upper portion of the receiving portion 200 is inserted into the pressing guide portion 210 and the receiving portion 200 The pressing guide portion 210 is rotatably installed.

The pressure guide portion 210 is formed with a thickness of the outer surface is smaller than the thickness of the inner surface, a portion of the outer surface of the pressure guide portion 210 is formed in a recessed shape in the direction of the inner surface of the pressure guide portion 210. do.

The operation of the cryogenic container according to the present invention having the configuration as described above will be described.

The inner space of the receiving portion 200 of the cryogenic container according to the present invention is the contents of the cryogenic temperature.

For example, to store a phase-change material as a liquid at room temperature under atmospheric pressure, such as nitrogen, lower the temperature below the critical temperature (-147.21 ° C for nitrogen) and change the phase to a liquid if an appropriate pressure is applied. do.

When nitrogen is stored in a liquid state rather than a gaseous state, it is economical and efficient because much more nitrogen can be stored in the same container.

Accordingly, the inner space of the accommodating part 200 of the cryogenic container is kept at a cryogenic state, and the liquid nitrogen (about -196 ° C.) is filled and sealed.

If the cryogenic container is shocked by the external environment after the contents are filled in the cryogenic container, a risk of explosion of the filled contents may occur.

Thus, in general, the cryogenic vessel is equipped with a safety valve, the conventional cryogenic vessel has a separate injection hole and the safety valve for injecting the contents, respectively.

Cryogenic vessel according to the present invention is formed integrally with the injection hole and the safety valve for injecting the contents of the structure as described above, thereby reducing the manufacturing cost and there is an effect that the manufacturing process is simplified.

After the contents are filled in the cryogenic container, when the cryogenic container is shocked or heated by the external environment and the pressure inside the cryogenic container rises, the ball of the guide part 130 is sealed by the spring member 120. As the safety valve 140 rises upward, the contents filled in the cryogenic container internal space are discharged to maintain a constant pressure in the internal space of the cryogenic container.

For example, the spring member 120 has a modulus of elasticity proportional to the magnitude of the pressure that the cryogenic vessel can withstand, so that if a pressure higher than the spring force of the spring member 120 is generated inside the cryogenic vessel, the pressure is safe. When the valve 140 is raised to discharge the contents filled in the cryogenic container, and the pressure inside the cryogenic container is lower than the strength of the spring member 120, the safety valve 140 is provided by the spring member 120. The air is sealed by the guide portion 130 to block the interior space of the receiving portion 200 is blocked.

In addition, since the inner space of the cover unit 110 is divided and sealed by the guide unit 130, the low-temperature contents discharged by the safety valve are not directly discharged to the discharge hole 160, but are heated in the divided space. It is discharged, and by the space formed between the upper surface 131 of the guide portion 130 and the inner surface 112 of the cover portion 110 can be prevented by the discharge of cold air due to the penetration of the external warm air.

In the case of the conventional cryogenic container, since the contents discharged by the safety valve are immediately discharged to the outside, there is a problem that can cause damage to the user or an external device, but the cryogenic container according to the present invention by the safety valve 140 Since the discharged contents are heated and discharged, there is an effect that the conventional problems are solved, and the external air flows into the accommodation portion 200 by the space formed between the guide portion 130 and the cover portion 110. It is prevented that the cold air inside the accommodating part 200 is prevented from being released.

In addition, when the pressing portion 330 is pressed in the direction of the receiving portion 200 in order to spray and use the contents filled in the cryogenic container, the filled contents are formed through the safety valve 140 and the injection hole 180 It is conveyed to the discharge pipe 310 through the), the transferred contents are to be injected to the outside through the injection nozzle (320).

In addition, since the pressing guide portion 210 is formed to prevent the malfunction of the pressing portion 330, when the cryogenic container is not used, the recessed portion of the pressing guide portion 210 is pressed into the pressing portion 330. If it is not located, the pressurizing portion 330 is not pressurized and the contents cannot be sprayed to prevent malfunction of the pressurizing portion 330, and when the user uses the cryogenic container, the pressure guide portion 210 is held in the hand. This can prevent the hand from slipping.

The embodiments and drawings attached to this specification are merely to clearly show some of the technical ideas included in the present invention, and those skilled in the art can easily infer within the scope of the technical ideas included in the specification and drawings of the present invention. It is apparent that all modifications and specific embodiments that can be included in the scope of the technical idea of the present invention.

1 is a perspective view of a cryogenic container according to the present invention.

2 is a cross-sectional view of the cryogenic container according to the present invention.

3 is a front view of the cryogenic container according to the present invention.

4 is a view of the safety cap of the cryogenic container according to the present invention.

5 is a cross-sectional view taken along the line A-A of FIG.

FIG. 6 is a cross-sectional view taken along line B-B of FIG. 4.

Figure 7 is an exploded perspective view of the safety cap of the cryogenic container according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: safety cap 110: cover

120: spring member 130: guide portion

140: safety valve 150: connection

160: discharge hole 180: injection hole

200: accommodating part 210: pressing guide part

300: injection unit 310: discharge pipe

320: injection nozzle 330: pressure unit

340: elastic member 350: opening and closing connection

360: opening and closing part

Claims (4)

One side is open, and the receiving portion is formed in the receiving space therein; A cover part having one side open and connected to seal the receiving part and having injection holes and discharge holes penetrating through the other side opposite to the open one side of the receiving part; A guide part installed inside the cover part to seal the open one side of the cover part, the guide part having a hole through which one side is formed; A safety valve installed to seal a hole formed in the guide part, and having a hole through which one side is formed; A spring member elastically supporting the safety valve; Is formed in the upper portion of the cover portion, is connected to the injection hole, and composed of an injection unit for injecting the contents contained in the receiving portion; The safety valve is an ultra low temperature container, characterized in that the lift in accordance with the pressure of the receiving space. The method of claim 1, Cryogenic vessel, characterized in that a space is formed between the inner surface of the cover portion and the upper surface of the guide portion. The method of claim 1, The injection unit, A discharge pipe having one end connected to the injection hole formed in the cover part; An injection nozzle having one side connected to the discharge pipe; One side is connected to the discharge pipe, ultra-low temperature container, characterized in that consisting of a pressurizing portion for controlling the injection. The method of claim 3, Both sides are open, the space is formed therein, and further comprises a pressure guide portion installed to surround the upper end of the receiving portion; The pressurizing guide part is a cryogenic container, characterized in that a part of the outer surface of the pressurizing guide part protrudes to prevent the pressurizing part.

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