KR20230095150A - Outer shell assembly of pressure vessel - Google Patents

Abstract

The present invention relates to a pressure container used to store various fluids such as oxygen, natural gas, and nitrogen, and more particularly, to a pressure container that can firmly and easily fix and remove an impact-resistant foam and an outer shell on the shoulder of the pressure container. It's about pressure vessels.
The present invention has a hollow interior, a dome-shaped shoulder portion is formed on one side or both sides, and a liner provided with a protrusion in the circumferential direction on the outer circumferential surface; an impact resistant member covering the shoulder portion; and an outer shell provided on the outside of the impact resistant member and having a hooking portion formed at an end portion to be caught on the protruding portion.

Description

Pressure vessel outer shell mounting structure {OUTER SHELL ASSEMBLY OF PRESSURE VESSEL }

The present invention relates to a pressure container used to store various fluids such as oxygen, natural gas, and nitrogen, and more particularly, to a pressure container that can firmly and easily fix and remove an impact-resistant foam and an outer shell on the shoulder of the pressure container. It's about pressure vessels.

The pressure vessel is used to store various fluids such as oxygen, natural gas, and nitrogen, and is recently used as a container for storing hydrogen, which is a fuel for eco-friendly hydrogen fuel cells.

Conventionally, a metal nozzle boss and a liner are manufactured, and carbon fibers or glass fibers are wound or laminated on the outside of the nozzle boss and the liner. However, high-pressure vessels made of conventional metallic liners have a problem in that they are heavy due to the nature of the metal, are very weak against corrosion, and have high manufacturing costs.

In order to solve this problem, a plastic liner using synthetic resin was manufactured, and due to the nature of plastic, it was possible to lighten the weight and improve corrosion resistance compared to metal materials.

1 and 2 show a conventional improved pressure vessel (1). Referring to this, first, the pressure vessel 1 forms a liner 10 of plastic material. The liner 10 has a hollow cylindrical shape, and both sides are provided with dome-shaped shoulder portions having curved cross sections.

In addition, a protective layer is formed by laminating carbon fibers 20 and glass fibers 30 on the outer circumferential surface of the liner 10, and a nozzle 60 for discharging gas is mounted.

In addition, a reinforcement part 40 for reinforcing the strength of the shoulder part vulnerable to pressure is provided. After the reinforcing part 40 is attached to the shoulder part, the carbon fiber 20 and the glass fiber 30 are wound and fixed to the liner.

In particular, in order to improve the fire resistance of the pressure vessel 1, a refractory material 50 is coated on the shoulder portion. The refractory material 50 is applied to the surface of the shoulder portion most vulnerable to pressure when the pressure vessel 1 is exposed to fire.

Typically, the refractory material 50 is coated with an epoxy resin as a binder on the shoulder portion by spraying. The epoxy resin has excellent weather resistance, reducing the risk of explosion when the pressure vessel is exposed to fire.

However, it is difficult to apply the epoxy resin in a uniform thickness when spraying. That is, the uniformity of the refractory material varies according to the skill level of the operator. In addition, when spraying, the waste of epoxy resin is severe.

However, when the pressure vessel is repeatedly exposed to high and low temperatures, when the refractory material applied to the surface of the pressure vessel repeatedly expands and contracts according to the temperature, it cracks or breaks and separates from the surface of the pressure vessel.

In this way, when the pressure container is exposed to fire while the refractory material is separated from the pressure container, the gas contained therein may explode, leading to a major accident.

If the refractory material is removed from the pressure container, maintenance is required. At this time, after separating the pipe connected to the pressure container, epoxy resin is applied again by spraying.

However, the work of separating the pipe in this way is also very cumbersome, and when reconnecting to the pipe after separation and maintenance, a complicated process such as a leak test is subsequently required.

Patent Registration No. 2250241 Patent Registration No. 1856323

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a pressure vessel that can be molded to a uniform thickness by providing an outer shell that prevents the dropout of the impact-resistant foam and is easy to replace for maintenance. is in providing

Another object of the present invention is to provide a pressure vessel with improved fire resistance to the pressure vessel by forming the outer shell of a flame retardant material.

Another object of the present invention is to provide a pressure vessel capable of replacing a damaged impact-resistant product and an outer shell without separating a pipe connected to the pressure vessel.

Another object of the present invention is to provide a pressure vessel in which an impact-resistant foam and an outer shell can be firmly and easily fixed and detached from the shoulder of the pressure vessel.

In order to solve the above technical problems, the pressure vessel according to the present invention has a hollow interior and a liner formed with a shoulder portion on one or both sides; an impact resistant member covering the shoulder portion; and an outer shell provided outside the impact resistant member to protect the impact resistant member.

In addition, it is preferable that the impact-resistant member is formed of non-combustible hard urethane foam.

In addition, the outer shell is preferably a flame retardant synthetic resin material.

In addition, it is preferable that the impact resistant member or outer shell is divided into at least two pieces.

In addition, it is preferable that a coupling groove is formed in the circumferential direction of the impact-resistant member or the outer shell, and a fixing member for fixing the divided impact-resistant member or the outer shell is seated in the coupling groove.

In addition, it is preferable that the divided impact resistant member or the outer shell is formed with different stepped portions at both ends to be shape-fitted.

In addition, the liner is preferably provided with a protrusion in the circumferential direction on the outer circumferential surface.

In addition, it is preferable that the outer shell has a hooking portion formed at an end portion bent to cover the protruding portion.

In addition, it is preferable that the coupling groove is formed on the upper part of the protruding part or in a center direction of the liner rather than the protruding part.

Preferably, the protruding portion is formed by winding carbon fiber or glass fiber around the outer circumferential surface of the liner in a circumferential direction.

According to the present invention, the shock-resistant foam made of non-combustible material protects the shoulder portion to protect the pressure vessel from external impact and has an effect of improving fire resistance.

In addition, it can be molded to a uniform thickness by injecting an outer shell that prevents the drop-off of the impact-resistant foam, and replacement for maintenance is easy.

In addition, by forming the outer shell of a flame retardant material, there is an effect of improving the fire resistance of the pressure vessel.

In particular, by dividing and forming the impact-resistant foam or outer shell into at least two parts, not only can only the damaged part be removed and replaced, but also the damaged impact-resistant product and outer shell can be replaced without separating the piping connected to the pressure vessel. there is.

In addition, there is an effect of firmly and easily fixing and removing the impact-resistant foam and the outer shell on the shoulder of the pressure container.

1 and 2 show a general pressure vessel.
3 and 4 show the overall configuration of the pressure vessel according to the present invention.
5 to 7 show the impact-resistant foam and the outer shell, which are main parts of the pressure vessel according to the present invention.
8 and 9 are cross-sectional views of a pressure vessel according to the present invention.

Hereinafter, the configuration and operation of the pressure vessel according to the present invention will be described in detail with reference to the accompanying drawings.

3 and 4, the pressure vessel 100 according to the present invention includes a liner 110 made of plastic or elastomer. The liner 110 has a hollow cylindrical portion and a dome-shaped shoulder portion having a curved cross section formed on both sides of the cylindrical portion.

A nozzle boss 120 through which fluid flows in and out is mounted on the liner 110 . The nozzle boss 120 is generally formed of a metal such as aluminum, brass, steel, or nickel alloy, but may be formed of a non-metallic material in some cases.

In addition, the protective layer 130 is formed by winding and laminating carbon fibers and glass fibers on the outer circumferential surface of the liner 110 .

4 and 5, the impact resistant foam 140 and the outer shell 150 are sequentially coupled to the shoulder portion.

The impact-resistant foam 140 is manufactured by foam-molding an incombustible hard urethane material in a mold. The impact-resistant foam 140 protects a shoulder portion vulnerable to external impact and pressure to improve fire resistance and impact resistance.

The impact-resistant foam 140 has an opening 141 formed in the center to expose the nozzle boss 120 .

In addition, in the present invention, the impact-resistant foam 140 may be manufactured in a shape and size capable of covering a portion of the shoulder portion from the nozzle boss 120.

However, more preferably, the impact-resistant foam 140 is manufactured in a shape and size capable of covering not only the entire area of the shoulder portion from the nozzle boss 120 but also a portion of the cylindrical portion of the liner.

The outer shell 150 is injection molded by injecting a flame retardant synthetic resin material, for example, a thermoplastic resin such as polyethylene, into a mold. Therefore, it is easy to manufacture the outer shell 150 with a uniform thickness, unlike spray coating of flame retardant resin.

The outer shell 150 protects the impact resistant foam 140 from external impact and improves the fire resistance of the pressure vessel 100 .

The outer shell 150 has an opening 151 formed in the center to expose the nozzle boss 120 .

The outer shell 150 is manufactured in a shape and size capable of covering the impact resistant foam 140 .

That is, the outer shell 150 may be manufactured in a shape and size capable of covering a portion of the shoulder portion from the nozzle boss 120, but the cylinder of the liner as well as the entire area of the shoulder portion from the nozzle boss 120. It is more preferable to be manufactured in a shape and size that can cover up to a part of the portion.

In addition, it can be seen that a coupling groove 155 is formed in the circumferential direction in the outer shell 150, and a clamp ('160' in FIG. 3) is seated as a fixing member in the coupling groove 155. The coupling groove 155 and the clamp 160 will be described in detail below.

Referring to FIG. 6, the impact resistant foam 140 according to the present invention can be divided into at least two pieces, and in this embodiment, the first foam member 140a, the second foam member 140b, and the third foam member 140a. It is divided and formed into three parts, such as the member 140c.

In particular, the first to third foam members 140a to 140c are formed with stepped portions 142 and 143 so that adjacent ends can be shaped and coupled to each other. Specifically, the first step portion 142 in the shape of 'L' is formed at one end, and the second step portion 143 is formed in the shape of 'L' at the other end, so that they can be coupled with each other stepwise. There is.

By forming the first and second stepped portions 142 and 143 in this way, the first to third foam members 140a to 140c can be easily coupled and aligned, and can be prevented from being separated from the shoulder portion. .

Referring to FIG. 7, the outer shell 150 according to the present invention can be divided into at least two, and in this embodiment, the first shell member 150a, the second shell member 150b, and the third shell The member 150c and the like are divided and formed into three parts.

In particular, the first to third shell members 150a to 150c are formed with stepped portions 152 and 153 so that adjacent ends can be combined by shape-fitting. Specifically, the first stepped portion 152 in the shape of 'L' is formed at one end, and the second stepped portion 153 is formed in the shape of 'L' at the other end, so that they can be coupled with each other stepwise. There is.

By forming the first and second stepped portions 152 and 153 in this way, the first to third shell members 150a to 150c can be easily coupled and aligned, and also prevented from being separated from the impact-resistant foam 140. can do.

In particular, the outer shell 150, that is, the first to third shell members 150a to 150c, have coupling grooves 155 formed along the circumferential surface at the outer end side.

The coupling groove 155 is a component for the clamp 160 to be seated.

Therefore, it is preferable that the coupling groove 155 be positioned at an upper portion of the cylindrical portion closer to the shoulder portion than the shoulder portion of the liner 110 .

By seating the clamp 160 in the coupling groove 155, not only can the first to third shell members 150a to 150C be fixed to each other, but also the first to third shell members 150a to 150c can be secured. It can be coupled to the impact resistant foam 140.

Furthermore, the clamp 160 also serves to fix the impact-resistant foam 140 to the liner 110 while fixing the first to third shell members 150a to 150c.

Meanwhile, in the present embodiment, the coupling groove 155 is formed only in the outer shell 150 and the clamp 160 is fixed. It is also possible to fix the impact-resistant foam itself to the liner 110 by means of a clamp (not shown).

For the clamp 160, for example, a known means such as a wire, a band, or a C-ring may be applied.

Since the impact-resistant foam 140 and the outer shell 150 are divided into two or more parts of the present invention, when a part is damaged by an external impact, only the damaged shell members 150a to 150c or the foam members 140a to 140c are removed. It has the advantage of being interchangeable.

In particular, in the present invention, since the impact-resistant foam 140 and the outer shell 150 are formed separately, when replacing part or all of the foam members 140a to 140c and the shell members 150a to 150c, the nozzle of the pressure container There is an advantage in that the pipe (not shown) connected to the boss 120 can be replaced without being separated. For reference, the pipe includes a tube connected to the nozzle boss and through which the fluid is transported, a fitting for airtightly connecting the tubes to each other, and a valve for adjusting the flow rate.

This is because if the impact-resistant foam 140 is integrally formed instead of being divided, the dome-shaped (or hemispherical) impact-resistant foam 140 can be removed only when all pipes connected to the nozzle boss 120 are separated. . If the outer shell 150 is also formed in a dome shape (or hemispherical shape) and integrally formed, there is no way to replace the impact resistant foam 140 and the outer shell 150 without separating the pipe.

In other words, although the impact-resistant foam 140 and the outer shell 150 are formed in a dome shape (or hemispherical shape), the present invention is composed of a plurality of divided assemblies, so that they are connected to the nozzle boss 120. It is possible to replace the impact resistant foam 140 and the outer shell 150 without separating the pipes.

In the present invention, it is possible to divide both the impact resistant foam 140 and the outer shell 150 as described above, but it is also possible to form the impact resistant foam 140 integrally and the outer shell 150 to be divided.

Conversely, it is also possible to form the outer shell 150 integrally and form the impact resistant foam 140 in parts.

In addition, it is possible to attach the impact-resistant foam 140 to the liner 110 with an adhesive and fix the outer shell 150 by means of the clamp 160, but, unlike the method, the impact-resistant foam 140 is fixed by the clamp 160. It is also possible to fix the outer shell 110 to the liner 110 and fix the outer shell 150 to the impact-resistant foam 140 with an adhesive.

8 is a cross-sectional view of a pressure vessel according to the present invention.

As shown, the nozzle boss 120 is coupled to the liner 110, a protective layer 130 such as carbon fiber or glass fiber is formed on the upper portion, and an impact-resistant foam 140 is provided on the shoulder portion, An outer shell 150 is provided on top of the impact-resistant foam 140.

In addition, by mounting a clamp 160 such as a wire in the coupling groove 155 formed in the outer shell 150, the outer shell 150 as well as the impact-resistant foam 140 can be fixed to the shoulder portion of the liner 110 will be.

9 shows a cross-sectional view of another embodiment according to the present invention.

As shown, the nozzle boss 120 is coupled to the liner 110, a protective layer 130 such as carbon fiber or glass fiber is formed on the upper portion, and an impact-resistant foam 140 is provided on the shoulder portion, An outer shell 150 is provided on top of the impact-resistant foam 140.

In addition, in that the outer shell 150 as well as the impact-resistant foam 140 are fixed to the shoulder portion of the liner 110 by mounting a clamp 160 such as a wire in the coupling groove 155 formed in the outer shell 150. It is the same as the embodiment shown in FIG. 8 .

In this embodiment, it can be seen that the protrusion 131 is formed in the circumferential direction on the outer circumferential surface of the liner 110 or the protective layer 130 .

The protruding portion 131 may be formed of the same material as the protective layer 130, such as carbon fiber or glass fiber.

That is, it can be formed to protrude from the liner 110 or the protective layer 130 by winding the carbon fiber or glass fiber along the circumferential direction.

Alternatively, it is also possible to form a ring-shaped protrusion 131 coupled to the outer circumferential surface of the liner 110 or the protective layer 130 . That is, the ring-shaped protrusion 131 is fixed to the top of the liner 110 or the protective layer 130 using an adhesive or other method.

In addition, in this embodiment, it can be seen that the end of the impact-resistant foam 140 is in contact with the side surface of the protruding portion 131, whereas the end of the outer shell 150 is formed with a bent hanging portion 154. The hooking portion 154 serves as a stopper to prevent the outer shell 150 from being detached from the shoulder portion by being in close contact with the protruding portion 131 .

Even in this case, a coupling groove 155 is formed on the outer circumferential surface of the outer shell 150 in the circumferential direction, and a clamp 160 such as a wire or a band is seated in the coupling groove 155 to prevent impact resistance from the outer shell 150 and the outer shell 150. The foam 140 is fixed to the shoulder portion of the liner 110.

The coupling groove 155 is formed on the side opposite to the nozzle boss 120 based on the protrusion 131, that is, in the center direction of the liner.

Alternatively, the coupling groove 155 may be formed on the upper part of the protrusion 131 .

100: pressure vessel
110: liner
120: nozzle boss
130: protective layer
140: impact-resistant foam
150: outer shell
160: protrusion

Claims (4)

A liner having a hollow interior, a dome-shaped shoulder portion formed on one side or both sides, and a protruding portion provided on an outer circumferential surface in a circumferential direction;
an impact resistant member covering the shoulder portion; and
and an outer shell provided on the outer side of the shock-resistant member and having a hooking portion formed at an end portion to be caught on the protruding portion.
According to claim 1,
The impact-resistant member or outer shell has a coupling groove formed in a circumferential direction,
A pressure container, characterized in that a fixing member for fixing the divided impact resistant member or the outer shell is seated in the coupling groove.
According to claim 2,
The pressure container according to claim 1 , wherein the coupling groove is formed on an upper portion of the protruding portion or in a direction toward a center of the liner rather than the protruding portion.
According to claim 1,
The pressure vessel according to claim 1 , wherein the protrusion is formed by winding carbon fibers or glass fibers around the outer circumferential surface of the liner in a circumferential direction.

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