JPH07229599A - Cylinder housing device - Google Patents

Abstract

PURPOSE:To place and store a cylinder inside an envelope in which coolant can be stored so as to provide a sufficient action for preventing fusion of a safety plug arranged in a cylinder main plug and so as to prevent scattering of cooling water to the surroundings. CONSTITUTION:Inside an envelope 112, fixing apparatuses 121 for fixing a cylinder 102 to be stored are provided in two positions. Inside the envelope 112, a discharge hole 107 for discharging stored coolant is arranged. The height of a side wall 101 of the envelope 112 is equal to the distance from a bottom part 102a of the cylinder 102 to a cylinder main plug 103 or more. Cooling water scattered from a sprinkler of a water storage tank is stored in the envelope 112 consisting of the steel cylindrical side wall 101. In this way, the cylinder main plug 103 can be immersed in cooling water without any leakage of the cooling water from the envelope 112 when the cooling water is sprinkled from the outside of the envelope 112 in emergency, for example. Therefore, a safety plug 104 arranged in a part of the main plug 103 can be directly cooled, and fusion of the safety plug 104 in exposure of the cylinder 102 to a high temperature environment can be prevented.

Description

Detailed Description of the Invention

[0001]

[Industrial application] A method of storing a cylinder for storing a gas or a liquid, particularly for a cylinder that prevents a substance filled in the cylinder from leaking when the cylinder is exposed to a high temperature environment. Concerning storage equipment.

[0002]

2. Description of the Related Art General gases such as nitrogen and hydrogen and silane (Si
Special material gases such as H ₄ ) are widely used in industry today as industrial gases. These gases are generally filled and stored in a cylinder made of manganese steel or aluminum alloy material. The cylinder is also filled with liquefied gas. In order to use the gas filled in these cylinders, after opening the main valve attached to the cylinders, the pressure of the filled gas is reduced by an appropriate pressure adjusting device and supplied to the gas consumption facility. .

These cylinders are originally high-pressure storage containers having pressure resistance so that they can be durable even when they are filled with gas under high pressure. However, when the cylinder is exposed to a high temperature environment, for example, the pressure of the gas filled in the cylinder is expected to rise abnormally. If the pressure of the filling gas rises above the pressure limit of the cylinder, the cylinder may burst. For this reason, a metal safety stopper is provided at the main stopper of the cylinder. This safety plug is made of a metallic material that melts at a certain temperature. When the safety plug is melted, the filling gas sealed in the cylinder container is released. This can prevent the pressure in the cylinder container from rising. Therefore, a safety stopper must be provided at the cylinder base stopper.

Such a high-pressure cylinder has been conventionally housed in a cylinder storage facility made of a nonflammable material such as steel.
This storage facility is called a cylinder cabinet or the like. FIG. 7 shows an example of a conventional general cylinder cabinet. Usually, it is a casing (113) having a side wall (101) made of a flat plate made of steel. Today's body (11
The front of (3) is usually equipped with a front door (113a). The cylinder (102) is housed in such a casing (113). The stored cylinder (102) is fixed to the column (120) by a fixing tool (121) such as a metal frame or a chain. The gas filled in the cylinder (102) is
It is supplied to the gas consuming facility through a piping system (115) connected to the main plug (103) of 2).

When the casing (113) and the cylinder (102) are exposed to a high temperature environment for some reason such as a fire, the safety plug (104) provided on the cylinder main plug (103) is melted and the cylinder (102) is melted. The gas filled into the housing is released into the housing (113) through the safety plug (104). In order to avoid such a situation, a cooling water sprinkling device (106) may be provided in the casing (113) in order to prevent the temperature of the cylinder (102) from rising. There is also a method of directly spraying cooling water on the casing (113) to lower the environmental temperature around the cylinder. Or today's body (11
3) There is also a method of installing sprinklers both inside and outside.

However, it has been customary in the past to provide a ventilation hole (105) in the cylinder cabinet for promoting ventilation in the same body. Therefore, the conventional cylinder cabinet is not completely sealed from the outside, and the cooling water or the like sprayed to cool the cylinder in the cabinet leaks to the outside of the cabinet through the ventilation hole (105) and the like. Further, even when water is sprinkled from the outside of the cabinet, conversely, if the gas leaks from the vent hole or other insufficiently sealed portion, the cooling water in which these gases are dissolved diffuses directly to the surroundings.

Some industrial gases may produce substances that enhance the acidity and alkalinity of cooling water by dissolution reaction. For example, when ammonia (NH ₃ ) gas is dissolved in water, it becomes ammonia water and becomes alkaline. That is, the cooling water sprinkled for cooling the cylinder container becomes alkaline, and an appropriate treatment of the cooling water is required. The treatment of cooling water sprinkled in a cylinder container filled with a gas containing a pollutant requires a more complicated treatment operation in order to prevent environmental pollution.

[0008]

However, conventionally, no equipment has been proposed which is capable of avoiding the temperature rise of the cylinder container and which is provided with both equipment for preventing the sprayed coolant from spreading to the surroundings. There is a demand for a method and a device for storing a cylinder that can be easily attached and detached, have the function of cooling the cylinder in an emergency, and can prevent the coolant from spreading to the surroundings. In the present invention, it has a sufficient cooling effect for the cylinder to avoid the dissolution of the safety stopper provided in the cylinder main stopper, and also has the effect of preventing the diffusion of the cooling water to the surroundings, which is sufficient for environmental pollution. Provide a thoughtful and safe storage device for the cylinder.

[0009]

When storing a cylinder containing a gas or a liquid, the cylinder is placed and stored in an envelope capable of storing a coolant. As the coolant, water, liquid nitrogen, liquid such as liquefied carbon dioxide, or solid such as ice or dry ice can be used. Water has the advantage of being extremely easy to handle in terms of storage and transport. On the other hand, although liquid nitrogen, liquid carbon dioxide, and dry ice are somewhat difficult to handle, their cooling capacity is remarkably excellent. Further, the envelope is a cylinder storage device including equipment for storing the coolant and a device for supplying the coolant into the envelope. The coolant is usually stocked in a separate storage container outside the envelope. This is because it is easy to attach and detach the cylinder. When water is used as the coolant, a water tank may be provided above the envelope so that water can be poured into the envelope in an emergency.

The envelope for storing the cylinder may be made of a material such as steel. It is convenient if the material is non-combustible.
A box whose one side is open is made of these materials.
The open surface may have a lid. Replace the cylinder inside the box from the open side. An example of a box-shaped envelope is shown in FIG. In the figure, the side wall (101) of the envelope and the bottom plate are made of flat steel plates. The top plate is open. Store the cylinder (102) in the envelope,
Or, on the contrary, to carry out the cylinder from the envelope. The side wall (101) and the bottom plate are welded to each other so as to store the coolant. Fixtures (121) for fixing the cylinder (102) to be stored are provided at two locations inside the envelope. (107) is a discharge hole for discharging the coolant stored inside the envelope.

The height of the side wall (101) of the envelope is from the lower portion (102a) of the cylinder (102) to the cylinder main plug (10).
The distance up to (3) (indicated by symbol h in FIG. 1) is preferably set to be equal to or greater than the distance. With this configuration, for example, when the cooling water is sprinkled from the outside of the envelope in an emergency, the cylinder main plug (103) can be immersed in the cooling water without leaking the cooling water from the envelope. Therefore, the safety stopper (104) provided in a part of the main stopper (103) can be directly cooled, and the cylinder (102) can be cooled.
It is possible to avoid melting of the safety stopper (104) when exposed to a high temperature environment.

FIG. 2 schematically shows a situation in which such water is put in and cooled. Reference numeral (106) in the figure denotes a cooling water sprinkling device supplied from a water storage tank (not shown) provided around the envelope. The cooling water sprinkled by the sprinkler (106) is stored in the envelope constituted by the cylindrical side wall (101) made of steel. Since the side wall (101) is higher than h, the cooling water can be stored up to a water level sufficient to cover the cylinder main plug (103) and the safety plug (104). The amount of water injected into the envelope may be set in advance so as not to exceed the inner volume of the envelope.

The envelope may be made of a flexible material. For example, the envelope may be made of a flexible, non-combustible cloth material. Installation and removal of the cylinder becomes easy. FIG. 3 shows an envelope including a flexible side wall (108) made of a flexible cloth material. Like the steel envelope shown in FIGS. 1 and 2, the top plate is open. This is because the cylinder (102) is taken in and out of the envelope. A fixture (121) made of a cloth band for fixing the cylinder (102) is provided at two locations inside the envelope. A coolant discharge hole (107) is provided at the bottom of the envelope.
It is convenient to post-treat the cooling water in the envelope.

To store the cylinder (102) in the envelope, a metal frame (11) supporting a flexible cloth side wall (108).
4) Lower towards the bottom of the envelope, reducing the height of the side wall (108). After that, the cylinder (102) is placed inside the envelope. The flexible fabric side wall (108) is then raised. The height of the side wall (108) is increased to a height at which a water level sufficient to cover the main plug (103) of the cylinder (102) with a coolant can be secured. If the support body that holds the height of the side wall (108) is installed, the height of the flexible side wall (108) can be maintained. Therefore, if the side wall of the envelope is made of a flexible material, it is necessary to store and replace the cylinder as compared to the case of the envelope made of the non-stretchable steel side wall as shown in FIGS. 1 and 2. There is an advantage that it can be done easily.

If the side wall is made of a material which is flexible and does not permeate or permeate cooling water or the like, the coolant can be stored inside the envelope. A discharge hole (107) for discharging the coolant stored inside the envelope may be provided on the side wall. Even if the gas component in the cylinder (102) reacts with the cooling agent and the cooling water is denatured, the denatured cooling water can be safely treated without diffusing.

Instead of supplying the coolant from the outside, the structure may be such that the coolant can be stored in the envelope itself. FIG. 4 shows a schematic cross-sectional view of an envelope capable of accumulating a coolant such as cooling water in the side wall portion and the lower portion. The side wall (101) is characterized by a double structure (109) for accumulating the coolant. Cooling water (110), for example, is accumulated inside the double structure (109). A part of the side wall (101) has a discharge plug (1) for discharging cooling water (110) inside the envelope.
11) is provided. When reaching a certain temperature, the discharge plug (1
11) is opened so that the accumulated cooling water (110) is automatically discharged into the inside of the envelope. It is convenient to install a plurality of discharge plugs because the time required to discharge the stored coolant into the envelope is shortened. When the side walls for storing the coolant are isolated from each other, it is preferable to provide a discharge stopper for each of the isolated storage locations.

When the coolant is stored in the envelope itself, the coolant is the main plug (10) of the cylinder (102) stored in the envelope.
3) It is enough to accumulate enough amount to cover. That is, it suffices if, for example, cooling water having a volume larger than the product value of the horizontal sectional area of the envelope and h can be accumulated. The temperature at which the discharge plug (111) is opened is set below the same temperature because the safety plug (104) of the cylinder melts at a temperature of 105 ° C.

FIG. 5 shows an example of a cylinder storage facility equipped with a conventional cylinder cabinet and a device capable of supplying a coolant from the outside of the envelope of the present invention. The envelope (112) according to the present invention is housed in a conventional casing (113). The side wall of the envelope (112) is made of a flexible cloth. The equipment illustrated in FIG. 5 has four cylinders (102).
It has an envelope (112) capable of storing. The cylinders (102) fixed inside the envelope (112) are fixed by the fixtures (121) provided inside the envelope (112).

A water sprinkler (106) for spraying cooling water is installed in the casing (113). The tip discharge port of the coolant sprinkler (106) is connected to the envelope (112).
If it is provided above, the coolant supplied from the tip end may be scattered around the outside of the envelope (112). Assuming that the component gas leaks from the cylinder, contaminated cooling water containing the component may be contained in the envelope (112).
Means to spread around. Therefore, it is preferable that the tip discharge port of the coolant external supply facility is installed inside the envelope. This is to ensure that the coolant is stored in the envelope and does not diffuse to the surroundings. If the side wall is made of flexible material,
A suitable support device is utilized to support and maintain the height of the sidewall metal frame (114).

[0020]

Function: The cylinder can be cooled efficiently, and there is an effect of preventing the diffusion of the coolant to the surroundings.

[0021]

EXAMPLES The present invention will be specifically described below based on examples. In the present embodiment, an example is given of a cylinder storage facility provided with an envelope made of a flexible nonflammable cloth side wall and an external water sprinkling facility. FIG. 6 shows an envelope (11 for storing a cylinder according to the present invention.
2 and 112a) is an external view of a cylinder cabinet. The envelopes (112 and 112a) are made of flexible flame-retardant cloth material. The bottom plate of the envelope was made of steel.

The flexible side wall (108) has a double structure and contains cooling water (110) inside. The distance between the double side walls was 10 cm. The double side wall structure is an envelope (1
12 and 112a) on the four side walls. The insides of the sidewalls were interconnected. Further, the height of the flexible side wall (108) is set to reach about 1.2 m when extended.

A high pressure gas cylinder (102) having an internal volume of 10 liters was housed inside the envelope (112 and 112a). The distance (h) from the bottom of the gas cylinder to the safety stopper (104) of the cylinder main stopper (103) was about 63 cm.
The horizontal cross section of the inside of the envelope (112 and 112a) was a square having a side of 40 cm, like the shape of the steel pedestal.
Therefore, the amount required to cover the cylinder safety plug (104) with cooling water was about 100 liters. This amount of cooling water was stored in the double-layered structure of the side wall and the hollow steel pedestal.

The cylinder (102) is surrounded by an envelope (112 and 1).
For storage in 12a), the flexible side wall (108) was first lowered. The flexible sidewall (108) can be easily lowered due to the flexible portion. This state is shown for one envelope (112a) in FIG. Next, the cylinder (10
2) was placed in the envelope (112a). After mounting, the main plug (103) of the cylinder (102) was connected to the piping system (115) equipped with a decompression facility for supplying gas consumption facility. After that, the metal frame (114) attached to the flexible side wall (108) was lifted to extend the side wall (108). The stretched sidewall was held at its height by the support (116). A cylinder (1 including the upper part of the main stopper (103)
02) is about 68 cm in height, and the stretched side wall metal frame (114) is about 50 mm further than the top of the main plug (103).
supported above cm. Therefore, the main stopper of the cylinder (103)
Can be covered with cooling water (110).

On the pedestal at the bottom of the side wall for storing the cooling water (110), discharge plugs (111) for discharging the cooling water (110) into the envelope (112) are provided at two locations. This is for efficiently discharging the stored water into the inside of the envelope. These discharge plugs (111) are automatically opened upon receiving a signal from a temperature measuring device (118) around the cylinder (102). In the present invention, the temperature around the cylinder is 70 ° C.
Then, the discharge plug (111) was set to automatically open.

A supply pipe (117) for supplying cooling water to the inside of the envelopes (112 and 112a) is further provided inside the casing (113). Enclosure (112 and 112a)
In addition to the cooling water accumulated on the double side wall of the
This is because the cooling water for cooling the cylinder (102) is also supplied from 7). A discharge hole (107) for discharging the cooling water stored inside the envelope (112 and 112a) is provided below the envelope (112 and 112a). The supply pipe (117) was composed of a steel pipe having a diameter of about 25 mm. The tip (117a) of the supply pipe (117) has an envelope (1
12 and 112a). The amount discharged from the discharge hole was set to the same level.

The supply pipe (117) from the outside of the envelope (112 and 112a) has a valve (119) in a part of the supply path.
Was set up. This valve (119) can also be automatically opened by an electric signal from the temperature measuring device (118).

[0028]

EFFECTS OF THE INVENTION It is possible to prevent dissolution of the safety stopper of the cylinder main stopper
Can safely store gas components without leaking to the outside.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of an envelope.

FIG. 2 is a diagram showing a state in which cooling water is stored in an envelope.

FIG. 3 is a schematic view of an envelope made of a flexible material.

FIG. 4 is a cross-sectional view of an envelope that can store a coolant.

FIG. 5 is an example of a cylinder storage facility equipped with an envelope that stores a coolant and a device that supplies the coolant.

FIG. 6 is another example of the embodiment of the cylinder storage facility equipped with the envelope storing the coolant and the device for supplying the coolant.

FIG. 7 is a diagram showing a configuration of a conventional cylinder cabinet.

[Explanation of symbols]

 (101) Side wall (102) Cylinder (102a) Cylinder bottom (103) Main stopper (104) Safety stopper (105) Vent hole (106) Sprinkler (107) Discharge hole (108) Flexible side wall (109) Double structure ( 110) Cooling water (111) Discharge plug (112) Enclosure (113) Body (113a) Body front door (113b) Body monitoring window (114) Metal frame (115) Piping system (116) Side wall support Body (117) Supply pipe (117a) Supply pipe tip (118) Temperature measuring device (119) Valve (120) Post (121) Fixing device (122) Coolant supply port

Claims (3)

[Claims] 1. An apparatus for storing a cylinder containing a gas or a liquid, wherein the container is capable of storing a cold storage agent together with the cylinder, a coolant storage facility, and the coolant. A cylinder storage device, which is equipped with a facility for supplying it inside. 2. The cylinder storage device according to claim 1, wherein the envelope is made of a flexible material. 3. The cylinder storage device according to claim 1, wherein the outer wall of the envelope has a structure for storing a coolant.