KR101919147B1 - shock absorbing device of air pressure vessel - Google Patents

Abstract

The present invention relates to a high-pressure vessel for storing or transporting CNG or liquid, comprising: at least one storage unit (100) for storing or supporting CNG or liquid at a pressure exceeding 200 bar; A connection part 200 provided at one side of each of the storage parts 100 and constituting a fluid passage between the storage parts 100; Upper and lower rack portions provided at both ends of the respective storage portions 100 and having a seating space corresponding to a shape of both ends of the respective storage portions 100 to fix and seat the respective storage portions 100; And a shock absorbing part 400 interposed between the respective storage parts 100 and absorbing shocks or vibrations applied to the respective storage parts 100 to prevent separation and mutual impacts APV (Air Pressure Vessel) shock absorber.
In another embodiment, the storage unit 100 may include at least one of storing or supporting CNG or liquid at a pressure exceeding 200 bar. Upper and lower rack portions provided at both ends of the respective storage portions 100 and having a seating space corresponding to a shape of both ends of the respective storage portions 100 to fix and seat the respective storage portions 100; And a shock absorbing part 400 interposed between the respective storage parts 100 and absorbing shocks or vibrations applied to the respective storage parts 100 to prevent separation and mutual impacts APV (Air Pressure Vessel) shock absorber.
According to the structure of the present invention, safety can be secured by providing a shock absorbing structure for preventing a shock or vibration generated when a pressure vessel mounted on a ship or the like is shaken and hits against each other.

Description

APV (Air Pressure Vessel) shock absorbing device (air pressure vessel)

The present invention relates to a high-pressure vessel for storing or transporting gas or liquid at high pressure. More particularly, the present invention relates to the structure of a container for storing or transporting compressed natural gas, liquid or the like at such a pressure.

The invention also relates to the construction of a vessel for storing or transporting a gas or liquid onshore or offshore.

For high pressure treatment, a mechanical complex is used comprising:

- closeable high pressure chamber,

A holding frame for holding the high pressure chamber during high pressure application,

A pivoting device which allows the high-pressure chamber to be pivoted laterally from the retaining frame,

At least one end-side closure for said high-pressure chamber,

A delivery device for causing the high-pressure medium to be delivered into the high-pressure chamber and to be taken out of the high-pressure chamber after the treatment process, and

- possibly a transfer device to cause the processing article to be transferred into the high-pressure chamber and to be taken out of the high-pressure chamber after processing, where the charging operation can of course be performed manually.

It has been found that it is convenient to design the high pressure chamber in the form of a cylinder due to the high pressure during high pressure treatment. The high-pressure chamber has one end, usually at both ends, and in each case one container closing means. To introduce the processing article into the high-pressure chamber, the high-pressure chamber is pivoted or transversely moved from the fixture in the open state. In the open state of the high-pressure chamber, the means for closing the container in the high-pressure chamber are anchored to the frame by the holding devices of the installation in general and are not fixed to the high-pressure chamber itself, i.e. not pivoted jointly.

An additional device is in charge of controlling the container closing means. When the articles are fed into the high pressure chamber, the high pressure chamber is pivoted or moved to the holding frame. In this position, the high-pressure chamber is closed and then locked by the container closing means or two container closing means using, for example, closing devices such as hydraulic cylinders. One of the container closure means typically has a fluid supply facility and a displaced air discharge device that has to be evacuated from the high pressure vessel during the inflow of fluid. In addition, one of the means for closing the container or the high-pressure vessel chamber itself is provided with a device for the inflow and outflow of high-pressure fluid.

There is a technical question here on how to design the holding and pressurizing devices of high-pressure vessels. A particular problem here is that it requires 6,000 to 10,000 bar, i.e. 600 to 1,000 hPa, to preserve. Even in the case of load-bearing parts of very large structures, the retaining frame, high-pressure vessel, closure means, hydraulic devices, circular opening means and sealing means will inevitably cause triaxial deformation. Here plastic deformation and leakage can occur, which should be avoided. It is the goal here that all devices must be able to operate without damage during 105 to 106 goods cycles.

Both the retaining frame supporting the high-pressure chamber and the high-pressure chamber itself, which absorb the very high pressure exerted by the operating pressure at the time of operation, are subjected to an autofrettage, pressure preloading by shrinkage or winding ), So that very high permissible working pressures can be applied. Accordingly, an appropriate safety factor for the yield stress of the material, respectively, is taken into consideration. By the preliminary load, it becomes possible to use an optimum material, so that a fixture subjected to a high-pressure stress can have durability. For example, WO 2005/079966 A1 describes a method of winding a high-pressure chamber.

WO 2010/102644 A1 discloses a high-pressure chamber comprising two cylinder portions connected axially by fastening elements, wherein the processing article is placed in a high-pressure chamber together with the pressure medium during high pressure processing Loses. The pressure chamber also has a prestressed casing wound in a steel band. The plugs of the pressure chambers are in each case held by a single winding framework, which can only move perpendicularly to the axis of the pressure chamber. Due to its structure, the risk of fastening elements abrading abruptly at the parting joints of the segments can be predicted.

Therefore, the present invention is based on the problem of providing a structurally simple facility and an economical method of applying a high pressure, and has a structure for replacing a manifold connecting the internal spaces of a plurality of high-pressure vessels, And to provide a structure having a structure for preventing vibration or shaking from external impact or vibration.

A high-pressure vessel for storing or transporting CNG or liquid, comprising: at least one storage or holding unit for storing or supporting CNG or liquid at a pressure exceeding 200 bar; A connection part 200 provided at one side of each of the storage parts 100 and constituting a fluid passage between the storage parts 100; Upper and lower rack portions provided at both ends of the respective storage portions 100 and having a seating space corresponding to a shape of both ends of the respective storage portions 100 to fix and seat the respective storage portions 100; And a shock absorbing part 400 interposed between the respective storage parts 100 and absorbing shocks or vibrations applied to the respective storage parts 100 to prevent separation and mutual impacts APV (Air Pressure Vessel) shock absorber.

The upper and lower racks may include at least one seating unit 310 having a shape corresponding to the shape of both ends of the storage unit 100. The upper and lower racks may have both ends of the storage unit 310 at a predetermined height And a guide part 420 having a structure in which the shock absorbing part is provided to support one side of the storage part.

The shock absorbing part 400 includes a fixed support plate 410 fixedly coupled to one side of the guide part, a storage part base plate 430 provided at one side of the storage part to support the storage part, And an elastic supporting part 420 interposed between the supporting part 410 and the storage part base plate 430 and absorbing shock or vibration applied to the storage part.

In addition, the shock absorber can be selectively replaced with the storage subsidy plate (430).

At this time, the shock absorbing part 400 is interposed between the guide part and the storage part, or interposed between the respective storage parts to absorb shock or external force applied to the storage part, .

As another embodiment of the present invention, there is provided a high-pressure vessel for storing or transporting CNG or liquid, comprising: at least one storage vessel 100 for storing or supporting CNG or liquid at a pressure exceeding 200 bar; Upper and lower rack portions provided at both ends of the respective storage portions 100 and having a seating space corresponding to a shape of both ends of the respective storage portions 100 to fix and seat the respective storage portions 100; And a shock absorbing part 400 interposed between the respective storage parts 100 and absorbing shocks or vibrations applied to the respective storage parts 100 to prevent separation and mutual impacts APV (Air Pressure Vessel) shock absorber.

The upper and lower racks may include at least one seating unit 310 having a shape corresponding to the shape of both ends of the storage unit 100. The upper and lower racks may have both ends of the storage unit 310 at a predetermined height And a guide part 420 having a structure in which the shock absorbing part is provided to support one side of the storage part.

The shock absorbing part 400 includes a fixed support plate 410 fixedly coupled to one side of the guide part, a storage part base plate 430 provided at one side of the storage part to support the storage part, And an elastic supporting part 420 interposed between the supporting part 410 and the storage part base plate 430 and absorbing shock or vibration applied to the storage part.

In addition, the shock absorber can be selectively replaced with the storage subsidy plate (430).

At this time, the shock absorbing part 400 is interposed between the guide part and the storage part, or interposed between the respective storage parts to absorb shock or external force applied to the storage part, .

According to the high-pressure vessel having the manifold function according to the embodiment of the present invention, the manifold can be replaced by the connecting portion provided between the storing portions, and the fuel and the pressure are shared between the storing portions. The effect of having a configuration of a high-pressure vessel that maintains a stable pressure is obtained.

On the other hand, it is advantageous in that it can be utilized not only at sea but also at the land, so that CNG storage can be utilized positively.

1 is a perspective view showing an installation state of an APV (Air Pressure Vessel) shock absorber according to an embodiment of the present invention.
2 is a perspective view showing an overall configuration of an APV (Air Pressure Vessel) shock absorber according to an embodiment of the present invention.
FIG. 3 is a perspective view showing a connecting portion of an APV (Air Pressure Vessel) shock absorber according to an embodiment of the present invention.
4 is a perspective view showing the configuration of upper and lower rack portions of an APV (Air Pressure Vessel) shock absorber according to an embodiment of the present invention.
5 is an exploded perspective view showing the entire structure of a high-pressure vessel having a manifold function according to an embodiment of the present invention.
FIG. 6 is a view showing a configuration and an installation state of the shock absorber among the APV (Air Pressure Vessel) shock absorber according to the embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. It is to be understood, however, that the spirit of the invention is not limited to the embodiments shown and that those skilled in the art, upon reading and understanding the spirit of the invention, may easily suggest other embodiments within the scope of the same concept.

1 is a perspective view showing an installation state of an APV (Air Pressure Vessel) shock absorber according to an embodiment of the present invention. 2 is a perspective view showing an overall configuration of an APV (Air Pressure Vessel) shock absorber according to an embodiment of the present invention. FIG. 3 is a perspective view showing a connecting portion of an APV (Air Pressure Vessel) shock absorber according to an embodiment of the present invention. 4 is a perspective view showing the configuration of upper and lower rack portions of an APV (Air Pressure Vessel) shock absorber according to an embodiment of the present invention. 5 is an exploded perspective view showing the entire configuration of a high-pressure vessel having a manifold function according to an embodiment of the present invention. FIG. 6 is a view showing a configuration and an installation state of the shock absorber among the APV (Air Pressure Vessel) shock absorber according to the embodiment of the present invention.

It is an object of the present invention to provide a high pressure vessel that is capable of withstanding substantially higher pressures than current designs. Thereby, a higher gas density can be achieved and thus the transport efficiency can be increased. In addition, the high-pressure vessel of the present invention must be light in weight, and due to the lighter vessels, the load-

Since a greater amount of gas / fluid can be transported to such an oceanic means of transport, for example, a vessel, without exceeding a certain amount (for example, pressurized gas or transported fluid) (Ie, a smaller percentage) would be due to the physical container. Finally, these vessels must have a high level of corrosion and damage resistance in order to be able to accommodate even the smallest facilities and treatments located in the burial sites.

CNG, on the other hand, may contain various potential constituents in variable mixing ratios, some of which may be in the gas phase and others in the liquid phase, or a mixture of both. The structural weight of the high-pressure vessel can be determined by weighing the empty high-pressure vessel-the vessel removed from any piping. However, given the size of the high-pressure vessel, the weight (mass) can often be a calculated or determined value. For example, when considering wall thickness, size and shape, and material composition, it will often be indicated on the certificate. This is to ensure that the appropriate structure can be supported and designed, for example, in the ship, to comply with the applicable regulations, as well as the ship's specifications, and appropriately applicable safety factors as determined by the relevant regulatory agency.

The present invention also provides a method of storing or transporting a gas, particularly a compressed natural gas, terrestrial or marine, using at least one high-pressure vessel, or a module or compartment as defined above, do.

As will be seen, a high-pressure vessel for storing or transporting CNG or liquid, comprising: at least one storage or holding unit for storing or supporting CNG or liquid at a pressure exceeding 200 bar; A connection part 200 provided at one side of each of the storage parts 100 and constituting a fluid passage between the storage parts 100; Upper and lower rack portions provided at both ends of the respective storage portions 100 and having a seating space corresponding to a shape of both ends of the respective storage portions 100 to fix and seat the respective storage portions 100; And a shock absorbing part 400 interposed between the respective storage parts 100 and absorbing shocks or vibrations applied to the respective storage parts 100 to prevent separation and mutual impacts APV (Air Pressure Vessel) shock absorber.

The upper and lower racks may include at least one seating unit 310 having a shape corresponding to the shape of both ends of the storage unit 100. The upper and lower racks may have both ends of the storage unit 310 at a predetermined height And a guide part 420 having a structure in which the shock absorbing part is provided to support one side of the storage part.

The shock absorbing part 400 includes a fixed support plate 410 fixedly coupled to one side of the guide part, a storage part base plate 430 provided at one side of the storage part to support the storage part, And an elastic supporting part 420 interposed between the supporting part 410 and the storage part base plate 430 and absorbing shock or vibration applied to the storage part.

In addition, the shock absorber can be selectively replaced with the storage subsidy plate (430).

At this time, the shock absorbing part 400 is interposed between the guide part and the storage part, or interposed between the respective storage parts to absorb shock or external force applied to the storage part, .

As another embodiment of the present invention, there is provided a high-pressure vessel for storing or transporting CNG or liquid, comprising: at least one storage vessel 100 for storing or supporting CNG or liquid at a pressure exceeding 200 bar; Upper and lower rack portions provided at both ends of the respective storage portions 100 and having a seating space corresponding to a shape of both ends of the respective storage portions 100 to fix and seat the respective storage portions 100; And a shock absorbing part 400 interposed between the respective storage parts 100 and absorbing shocks or vibrations applied to the respective storage parts 100 to prevent separation and mutual impacts APV (Air Pressure Vessel) shock absorber.

The upper and lower racks may include at least one seating unit 310 having a shape corresponding to the shape of both ends of the storage unit 100. The upper and lower racks may have both ends of the storage unit 310 at a predetermined height And a guide part 420 having a structure in which the shock absorbing part is provided to support one side of the storage part.

The shock absorbing part 400 includes a fixed support plate 410 fixedly coupled to one side of the guide part, a storage part base plate 430 provided at one side of the storage part to support the storage part, And an elastic supporting part 420 interposed between the supporting part 410 and the storage part base plate 430 and absorbing shock or vibration applied to the storage part.

In addition, the shock absorber can be selectively replaced with the storage subsidy plate (430).

At this time, the shock absorbing part 400 is interposed between the guide part and the storage part, or interposed between the respective storage parts to absorb shock or external force applied to the storage part, .

According to the present invention, the present invention provides a structurally simple facility and an economical method of applying a high pressure, and it is an object of the present invention to provide a method for replacing a manifold that connects internal spaces of a plurality of high- A plurality of high-pressure vessels are fixed and seated, and a structure having a structure for preventing shaking or the like from external shocks or vibrations is provided.

According to the configuration of the APV (Air Pressure Vessel) shock absorber according to the embodiment of the present invention, the function of the manifold can be replaced through the connection portion provided between the storage portions, The effect of having a configuration of a high-pressure vessel that maintains a stable pressure is obtained.

On the other hand, it is advantageous in that it can be utilized not only at sea but also at the land, so that CNG storage can be utilized positively.

100. Storage 200. Connection
300. Upper and lower shelves 400. Shock absorbers
310. Seat part 320. Guide part
410. Fixed support plate 420. Elastic support
430. Storage area fingerboard

Claims (10)

As a high-pressure vessel for storing or transporting CNG or liquid,
At least one storage unit (100) for storing or supporting CNG or liquid at a pressure exceeding 200 bar;
A connection part 200 provided at one side of each of the storage parts 100 and constituting a path for fluid movement between the respective storage parts 100 and acting as a manifold;
Upper and lower rack portions provided at both ends of the respective storage portions 100 and having a seating space corresponding to a shape of both ends of the respective storage portions 100 to fix and seat the respective storage portions 100;
And a shock absorbing part 400 interposed between each of the storage parts 100 and the upper and lower rack parts and absorbing shocks or vibrations applied to the respective storage parts 100 to prevent separation and mutual impacts and,
The shock absorber (400) is provided with a plurality of resilient supporters having a predetermined elastic force to absorb shocks and vibrations transmitted to the respective storage units.
The method according to claim 1,
The upper and lower racks
At least one seating part 310 having a shape corresponding to the shape of both ends of the storage part 100,
And a guide unit 320 having both ends of the storage unit 100 mounted at predetermined heights and supporting the one side of the storage unit with the shock absorbing unit. Pressure Vessel) Shock Absorber.
3. The method of claim 2,
The impact absorbing portion 400 is formed of a metal,
A fixed support plate 410 fixedly coupled to one side of the guide portion,
A storage part base plate 430 fixed to one side of the storage part and supporting the storage part,
And an elastic support part 420 interposed between the stationary support plate 410 and the storage part base plate 430 to absorb shock or vibration applied to the storage part. Shock absorber.
The method of claim 3,
Wherein the shock absorbing portion comprises:
Wherein the stationary support plate (410) is selectively replaceable with a storage subsidy plate (430).
The method according to claim 3 or 4,
The impact absorbing portion 400 is formed of a metal,
And an air pressure vessel shock absorber (20) interposed between the guide part (20) and the storage part (20) or interposed between the storage parts (20) to absorb and absorb shock or external force applied to the storage part .
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