JP3148131B2 - Gas supply system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas supply system, and more particularly to a gas supply system capable of simply supplying gas when an existing pipe cannot be used or when an airtight test of the pipe is performed.

[0002]

2. Description of the Related Art Pipes such as gas pipes buried in the ground are damaged by external forces due to disasters such as earthquakes, for example.
You may not be able to use it. Conventionally, when a part of a pipe is replaced or repaired depending on the type of gas supply destination, the following method is adopted. When exchanging a part of the service pipe that is branched from a conduit buried underground through a service tree and drawn into a private area such as a single-family house, the gas supply to the house must be changed. Temporarily stop, after the replacement work is completed, perform an airtight test in the piping, confirm that there is no gas leakage, and start resupplying the gas. On the other hand, when replacing or repairing pipes that are installed in multiple houses where gas usage is not uniform unlike single-family houses, supply pipes drawn from conduits A temporary bypass path is provided between the conduit and a portion of the gas flow direction downstream of the valve installed in the pipe, and the supply of gas is maintained through the bypass path, while the bypass path is maintained. The supply pipe side valve is closed and the supply pipe is replaced or repaired.

[0003]

When the supply of gas is stopped when a part of the pipe is replaced, it is necessary to request the user of the gas to stop using the gas. It is necessary to make PR such as notification thorough. However, even if it is determined that the advance notice has been received, there is a case where the user is out of home or the like, and it may be difficult to perform management before starting the replacement work. Moreover, if there is no home, the waiting time until the ignition test of the gas appliance after the replacement work may increase, and in the case of an apartment house, inconvenience occurs until the resupply of gas. Sometimes. In addition, when installing a bypass, it is necessary to perform work different from the original work, such as laying and removing the bypass, in addition to replacing the pipes. This increases the time required for replacement and resupply of gas. In addition, when it is necessary to supply gas to the supply destination when replacing or repairing piping,
Leakage of gas from the pipes to be replaced or repaired may occur.Therefore, it is necessary to take sufficient safety measures such as not to generate fire or heat on the supply side. Careful work is required. On the other hand, apart from the case where the existing pipes cannot be used, there is a case where a simple gas supply is desired, for example, in an airtightness test of pipes at a commercial demand destination such as a building. Conventionally, when performing an airtightness test on pipes in a building equipped with a large number of pipes, the gas flow from the medium-pressure pipe used to supply gas to commercial customers is cut off, and air is flowed instead. Air tightness test. However, such a method requires an operation for removing air remaining in the pipe after the end of the airtight test, that is, a so-called purging operation, so that the gas supply cannot be started immediately after the end of the test. . An object of the present invention is to provide a gas supply that can be maintained when an underground pipeline cannot be used or when a simple supply of gas is demanded, in view of the above-described problem that the conventional gas supply is interrupted. Another object of the present invention is to provide a gas supply system capable of sufficiently ensuring safety during supply.

[0004]

In order to achieve this object, according to the first aspect of the present invention, a gas-filled high-pressure container is located on an input side, and a connection portion with a gas supply destination is located on an output side. In the gas supply path, a plurality of the high-pressure vessels are arranged on the input side, and gas in one high-pressure vessel selected from the plurality of high-pressure vessels is taken in. The pressure is reduced to the final pressure used at the gas supply destination by a plurality of pressure reducing sections,
The gas passing between the decompression sections is introduced into the heat exchange section to correct the temperature, and when the pressure of the gas reaching the output side is higher than a predetermined final pressure, the gas is released to the atmosphere or the flow of the gas is shut off. It is characterized by doing so.

According to a second aspect of the present invention, there is provided a gas supply path in which a gas-filled high-pressure container is located on an input side and a connection portion with a gas supply destination is located on an output side. A primary side decompression section and a secondary side decompression section disposed between the pressure reduction sections, a heat exchange section is disposed between the pressure reduction sections, and a predetermined pressure or more is applied to a gas discharge side of the heat exchange section. An emergency shut-off unit capable of shutting off gas supply to the primary-side depressurizing unit by the discharge pressure is provided, and the gas discharge unit of the secondary-side depressurizing unit shuts off gas supply to the connection unit side in an emergency. A gas supply control unit provided with a fuse plug is provided.

According to a third aspect of the present invention, in the gas supply system according to the first aspect, the high-pressure vessel disposed on the input side has a pipe line leading to a first-stage pressure reducing section of the pressure reducing section. An opening / closing valve is arranged in a pipe line before being combined so that a path for taking in gas from a high-pressure container can be selected.

According to a fourth aspect of the present invention, in the gas supply system according to the second aspect, the emergency shut-off portion is constituted by a pressure-operated valve operated by a gas having a predetermined pressure or higher. .

According to a fifth aspect of the present invention, in the gas supply system according to the second aspect, the high-pressure container, the connection part, and the gas supply control part are mounted on a truck and can be transported to a supply destination. I have.

The invention according to claim 6 is the first or second invention.
In the gas supply system described above, the heat exchange unit is configured by a plurality of finned tubes of an atmosphere contact type.

According to a seventh aspect of the present invention, there is provided a gas supply system according to one of the first, second and sixth aspects,
The heat exchange section is characterized in that a gas passage length is set to at least a length through one turn.

The invention according to claim 8 is the first or second invention.
In the gas supply system described above, a plurality of the high-pressure vessels can be mounted on the cart, and check valves are respectively arranged in pipes from the high-pressure vessels to prevent gas from flowing back to the supplied vessels. It is characterized by.

[0012] The ninth aspect of the present invention is the first or second aspect.
In the gas supply system described above, a means for detecting the pressure of the gas reduced to the final pressure is disposed in a pipeline leading to a connection with a gas supply destination located on the output side. .

According to a tenth aspect of the present invention, in the gas supply system according to the first or second aspect, the pressure of the gas flowing through the pipeline is predetermined before reaching the pressure reducing section for reducing the pressure to the final pressure. It is characterized in that means for releasing gas to the atmosphere when the pressure is equal to or higher than pressure is provided.

According to an eleventh aspect of the present invention, in the gas supply system according to the second aspect, the gas discharge part of the secondary-side pressure reducing part has a fuse plug for interrupting the supply of gas to the connection part in an emergency. In addition, an on-off valve is provided.

According to a twelfth aspect of the present invention, in the gas supply system according to the second or eleventh aspect, the gas discharge part of the secondary side pressure reducing part reaches the gas discharge part in addition to the fuse plug and the on-off valve. A relief valve for releasing gas to the atmosphere when the gas pressure is equal to or higher than a predetermined pressure is provided.

[0016]

According to the first and third aspects of the present invention, one of a plurality of high-pressure vessels is selected to take in gas.
The taken-in gas is supplied by being reduced in pressure to a final pressure corresponding to the pressure at the gas supply destination by a plurality of stages of pressure reducing units. The member for correcting the gas passage can be prevented from deteriorating due to the temperature. In addition, when the gas pressure at the supply destination is higher than the predetermined pressure, it is possible to prevent the gas from being supplied and prevent the gas from being blown out due to the abnormal pressure, thereby eliminating the cause of ignition. become.

According to the second, fourth to sixth and eighth aspects of the present invention, the temperature drop due to the adiabatic expansion at the time of pressure reduction is corrected only by contacting the atmosphere of the use environment without using an energy source such as a heating source or a power source. Therefore, an energy source that causes ignition can be eliminated. Moreover,
Since the structure of the temperature adjustment unit can be reduced in size, the supply control unit can be transported by a cart, so that the temperature control unit can be easily installed in a place where gas supply is required.
Further, since the shut-off unit for shutting off the gas when the pressure of the depressurized gas is equal to or higher than the predetermined pressure is operated by the gas itself having reached the predetermined pressure or higher, without adding a special structure. The size of the device used in the gas supply system can be reduced.

According to the seventh aspect of the present invention, the correction of the temperature of the gas which is reduced at the time of depressurization can be performed with the minimum necessary gas passage length. Can be reduced in size.

According to the ninth to twelfth aspects of the present invention, the supply pressure of the gas at the supply destination is monitored, and when the pressure reaches a predetermined pressure or more, the supply of the gas to the supply destination is automatically stopped. In addition, the cause of ignition due to abnormally high pressure gas at the supply destination can be eliminated.

[0020]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. FIG. 1 is a schematic diagram for explaining the concept of a gas supply system according to an embodiment of the present invention. In FIG. 1, the gas supply system of the present invention fills a gas pipe (service pipe) 2 to be supplied with city gas irrespective of repairing or replacing the main pipe 1 buried underground. High pressure vessel 3
The gas is supplied simply from. When supplying gas from the high-pressure vessel 3, the gas pipe 2 drawn into the private area
A part of the meter stand 5 to which the gas meter 4 is attached is opened continuously, and a coupler provided on the output side of the gas supply device 7 described later is connected to the opening.

The above-described gas supply device 7 is a feature of the present invention. As shown in FIG. 2, a gas supply control unit 9 mounted on a cart 8 and a high-pressure container 3 filled with city gas are provided. And a gas supply unit 11 including a corresponding cylinder 10. The cart 8 has a mounting portion 8A on which a plurality of cylinders 10, two in this embodiment, can be mounted, and a gas supply control portion 9 is provided adjacent to the mounting portion 8A.

FIG. 3 is a block diagram for explaining the relationship between the gas supply control section 9 and the gas supply section 11 described above. In FIG. container vessel 2 Nm ³ / the city gas filling 10L (liter) under a pressure of 10 Nm ³ / bomb town gas filled book and 200 Kg / cm ² of 50L (liter) under a pressure of cm ² Two systems are set to use the set cylinder (in FIG. 3,
For a plurality of cylinders, numerals 50L and 10L indicating the capacities of the cylinders are attached. ).
Note that the capacity of the cylinder is not limited to the above-mentioned capacity, but can be selected according to the specifications at the supply destination. The pipes from each system are collected at appropriate locations and connected to the primary-side pressure reducing unit 12. A check valve 11a is disposed in the piping of each system to prevent gas from flowing backward from an unused cylinder 10 to a supplied cylinder. Further, the gas pressure in each system can be monitored by the pressure gauge 11b, so that a replacement operation with a new cylinder 10 and an abnormality detection can be performed at the time when the gas in the cylinder is completely supplied. . At the time of replacement of the cylinder 10, it is necessary to shut off the gas in the system in which the cylinder 10 requiring replacement is arranged. Therefore, a manually operable on-off valve 11c is installed in the system.

In FIG. 3, in the supply path of the gas supplied from the gas supply unit 11, when the gas supply unit 11 side is set as the input side and the coupler 50 forming the connection part with the supply destination pipe is set as the output side, In the meantime, a plurality of pressure reducing sections, in this embodiment,
A primary-side decompression unit 12 and a secondary-side decompression unit 13 are provided along the gas supply direction. Each of the primary and secondary pressure reducing sections 12, 13 is provided with a regulator valve 12a, 1
3a is used, and in the primary side decompression section 12, 200 K which is the filling pressure of the city gas filled in the cylinder 10 is used.
A pressure-regulating characteristic for reducing g / cm ² to 5.0 kg / cm ² is set, and the secondary-side pressure reducing unit 13 supplies the gas pressure reduced by the primary-side pressure reducing unit 12 to a supply destination such as a general household. A pressure regulation characteristic for reducing the pressure to 240 mmAq is set. In FIG. 3, the numbers assigned to the primary and secondary pressure reducing sections 12 and 13 and the numbers assigned to the valves described later indicate the input pressure and the output (reduced pressure) pressure, respectively.

The primary side decompression section 12 is provided with a relief mechanism when the pressure of the decompressed gas reaches a predetermined pressure or more. As the relief mechanism, a relief valve 12b composed of an angle valve arranged on the output side of the primary pressure reducing unit 12 is used. The relief valve 12b is a pressure reduced by the primary pressure reducing unit 12 at 5 kg / kg. When a pressure of 8 kg / cm ² higher than cm ² is reached, an over-pressure gas can be released to the atmosphere.

A predetermined pressure (5 kg /
A secondary pressure reducing unit 13 is disposed on the side to which the gas decompressed to cm ² ) is supplied, and a heat exchange unit 14 is disposed in front of the secondary pressure reducing unit 13. Heat exchange unit 1
4, a finned tube that can be brought into contact with the atmosphere and does not require a power source or a heat source for heating is set to a predetermined length and connected in series, and is adiabatically expanded in the primary-side decompression unit 12. Thus, the temperature of the gas whose temperature has been lowered is adjusted to the ambient temperature of the use environment. The finned tube constituting the heat exchanging section 14 is set to have a length of gas passing through at least one turn, and in this embodiment, a length of gas passing through five turns. Have been. As described above, the length of the passage including the folded portion is set in consideration of the ability to transfer the heat required for regenerating the temperature and preventing the height of the gas supply device 7 from increasing.

An emergency shutoff unit 15 is connected to the gas discharge unit of the heat exchange unit 14. The emergency shutoff unit 15 includes a check valve 16, a balance valve 17, and a shutoff valve 18 arranged in a pipe communicating with the gas discharge unit in the heat exchange unit 14. When the pressure of the gas discharged from the heat exchange unit 14 is reduced by the primary pressure reducing unit 12 and the pressure of the gas discharged from the heat exchange unit 14 reaches a specified value or more, the balance valve 17 causes the gas itself to act on the shut-off valve 18, The pipe opening / closing member (not shown) provided in the above can be operated to close the pipe. Usually, 5 kg / cm ² which is a gas pressure reduced by the primary side pressure reducing section 12 is applied. In this state, the pipe opening / closing member of the shut-off valve 18 is not operated, and when a pressure of 7 kg / cm ² higher than the gas discharge pressure at the primary pressure reducing unit 12 acts as the specified pressure, the gas at that pressure is shut off. 18 to actuate the pipeline opening / closing member. The specified pressure set in the balance valve 17 is a withstand pressure in a pipe from the gas output part (discharge part) of the primary pressure reducing part 12 to the gas input part of the secondary pressure reducing part 13 via the heat exchange part 14. (9.9 K / cm ² ) and the gas discharge section (output side) of the primary side decompression section 12 including the destruction of the finned tube constituting the heat exchange section 14.
This is to prevent damage to the pipeline from to the gas input unit of the secondary pressure reducing unit 13. The shut-off valve 18 is disposed in a pipeline upstream of the primary pressure reducing unit 12, and is configured by an on-off valve provided with a pipeline opening / closing member (not shown) therein, and a secondary valve acting on the balance valve 17. When the gas pressure on the gas input side of the side pressure reducing unit 13 reaches a specified value or more, the pipe opening / closing member is operated to close the gas supply path to the primary side pressure reducing unit 12 and shut off the gas.

A part of the pipe leading to the shut-off valve 18 is branched into the emergency shut-off section 15, and a warning member 19 is connected to the branched pipe.
And the atmosphere discharge part 20 are connected. Warning member 19
Although not shown in detail, the present embodiment has a configuration in which the present embodiment has a window provided at the end of the conduit, and a warning indicator is fitted inside the window. When the pressure of the gas input to the secondary-side pressure reducing unit 13 is equal to or lower than the specified pressure, the warning display body normally exposes the white film to the outside from the window, and is input to the secondary-side pressure reducing unit 13. When the pressure of the gas reaches a predetermined pressure or more, the gas having the pressure causes the red sphere to protrude from the white film and to be exposed from the window.

The atmospheric discharge unit 20 is constituted by an on-off valve, and after the supply of gas to the input side of the primary pressure reducing unit 12 is shut off,
When the gas shutoff state to the primary side pressure reducing section 12 is released, the gas that is opened and acts on the balance valve 17 and the shutoff valve 18 is released to the atmosphere.

On the other hand, the pipe of the gas discharged from the heat exchange section 14 is branched into a path toward the secondary pressure reducing section 13 in addition to a path toward the emergency cutoff section 15 described above. The secondary pressure reducing unit 13 is in an open state with a predetermined pressure (5 kg / cm ² ) reduced by the primary pressure reducing unit 12 as a specified pressure. The secondary pressure reducing unit 13 is provided to reduce the pressure of the gas reduced by the primary pressure reducing unit 12 to a supply pressure at a supply destination such as a general home. , A relief valve 21 for venting to the atmosphere in case of excessive pressure is arranged. The relief valve 21
The discharge pressure of the gas decompressed by the secondary decompression unit 13 is higher than a predetermined pressure (240 mmAq) (240 mmAq).
0 mmAq), excess gas is released to the atmosphere, and a pressure higher than that value and conversely 150 mmAq
It has a function to shut off gas when the following pressure is reached. Atmospheric release of the relief valve 21, secondary pressure reducing unit 1
In the event that 3 is damaged, the decompression function cannot be obtained, thereby preventing the gas pressure from becoming abnormally high.
Further, it has a shut-off function for stopping the supply when an abnormal decrease in the pressure in the cylinder 10 or an abnormal situation in the pipe of the supply path occurs.

A fuse plug 22 is connected to a gas discharge section of the secondary pressure reducing section 13. The fuse plug 22 is provided with an open / close valve provided to prevent a secondary disaster from occurring when raw gas is directly blown out in an emergency when the connection portion comes off, that is, when it comes off. When the flow rate of the gas discharged from the side pressure reducing section 13 reaches 6 m ³ / h, the gas outlet side pipeline can be shut off. The fuse plug 22 has an on-off valve 22 corresponding to an outlet valve.
The on-off valve 22a is closed when the pipe on the output side is closed by the fuse plug 22, and after the gas is released to the atmosphere at the air release section in the supply path to the output side. Closed again. Further, near the fuse plug 22, a pressure gauge 23 for detecting the pressure in this pipeline is provided.
Are connected.

Since the present embodiment has the above configuration,
The gas supply control unit 9 is mounted on the trolley 8, while a cylinder 10 filled with a required amount of city gas at a required pressure is set in the gas supply unit 11, and a hose located on the input side of the gas supply control unit 9 is installed. Is connected to the cylinder 10. The cart 8 on which the gas supply control unit 9 and the cylinder 10 are mounted
As shown in FIG. 1, the main pipe 1 or the service pipe 2 corresponding to the replacement or repair section is transported to a supply destination where the main pipe 1 or the service pipe 2 is buried.

The truck 8 conveyed to the supply destination is connected to a coupler 50 serving as a connecting portion located on the output side of the supply path in the gas supply control section 9 by, for example, a meter standing pipe (reference numeral 5 in FIG. 1).
(Member indicated by). When the input side of the supply path in the gas supply control unit 9 is connected to the cylinder 10 and the output side is connected to the meter stand, gas supply is started.

When supplying gas, the gas supply control unit 9
Then, the pressure inside the cylinder 10 is confirmed by the pressure gauge 11b provided in the gas supply unit 11, and when the pressure is usable, one of the on-off valves 11c is opened, and further, the outlet valve indicated by reference numeral 22a in FIG. The corresponding on-off valve is opened. When the on-off valve 11c is opened, gas is supplied from the selected cylinder 10 to the input side of the gas supply control unit 9.

In the gas supply control section 9, the gas discharged from the cylinder 10 is supplied to the primary side pressure reducing section 12,
200 kg / cm ^2, which is a pressure within 0 to 5 kg / c
The pressure is reduced to m ² . Although the temperature of the decompressed gas has been lowered due to adiabatic expansion that occurs during decompression, the gas is adjusted to a use environment temperature by passing through the heat exchange unit 14 and supplied to the secondary-side decompression unit 13.

Since the heat exchange section 14 uses an atmosphere contact structure that does not require a power source or a heat source to raise the temperature of the gas whose temperature is decreasing, it does not have a factor that ignites the supplied gas. In this way, safety in gas handling can be ensured. The gas passing through the heat exchange unit 14 is prevented from passing through the pipeline at the temperature lowered by the adiabatic expansion due to the correction of the temperature, thereby preventing the equipment from being damaged due to the temperature drop.

On the other hand, the pressure of the gas decompressed by the primary side decompression section 12 becomes higher than 5 kg / cm ² and becomes 7 kg
/ Cm ² , the emergency cut-off unit 15 closes the input-side conduit connected to the primary-side depressurizing unit 12 and shuts off the gas. That is, the pressure of the gas supplied from the primary side decompression unit 12 to the secondary side decompression unit 13 is 5 kg / cm.
^When the pressure is equal to or greater than 2, when the pressure of the gas input to the secondary pressure reducing unit 13 reaches a specified value or more, the emergency shutoff unit 15 is operated. In the emergency shutoff unit 15, when a gas pressure equal to or higher than a specified pressure acts on the balance valve 17, the equilibrium state up to that point is disrupted and the pipe opening / closing member of the shutoff valve 18 is operated, so that the gas to the primary side pressure reducing unit 12 is reduced. Is closed. Further, at this time, since the warning indicator in the warning member 19 exposes a red sphere from the window,
It can be easily confirmed from the outside that the emergency shutoff unit 15 is operating. As described above, when a pressure that affects the pressure resistance of the components of the pipeline is generated in the pipeline until the gas discharged from the primary-side vacuum unit 12 is input to the secondary-side vacuum unit 13. Since the supply of gas is shut off in the pipeline, damage to the pipeline from the primary-side depressurizing section to the secondary-side depressurizing section can be avoided beforehand, and the state can be easily confirmed from the outside.

The predetermined pressure 5 in the primary pressure reducing section 12
The gas decompressed to Kg / cm ² is supplied to the secondary-side decompression unit 13 only when the pressure is a specified decompression pressure, and decompressed to 240 mmAq, which is the working pressure at the supply destination. In the secondary pressure reducing unit 13, when the input gas pressure becomes higher than 5 kg / cm ² , the gas of the pressure acts on the emergency shut-off unit 15, and the pressure of the gas reduced by the secondary pressure reducing unit 13 is reduced. When the pressure reaches 420 mmAq, the excess pressure
1 to the atmosphere. Further, when the pressure of the decompressed gas is higher than 420 mmAq,
If it becomes lower than mmAq, it is shut off. Thus, the decompressed gas is supplied to the fuse plug 22 only when the decompressed pressure is maintained at a specified decompressed pressure. Since the pressure at this time is detected by the pressure gauge 23, it can be monitored from outside.

The gas set to the final pressure at the destination by the secondary pressure reducing unit 13 is supplied to the destination via the fuse plug 22. When the flow rate of the gas depressurized by the secondary pressure reducing unit 13 has reached a predetermined value (6 m ³ / h) or more, the gas outlet side pipe line is closed by the fuse plug 22 and the gas supply is cut off. Is done. This prevents a raw gas supplied from the secondary side decompression unit 13 from being blown out in an emergency such as a disconnection of the connection part, and causes a secondary disaster that may occur when the raw gas is blown out. Not to be.

According to the present embodiment as described above, it is determined that the gas pressure becomes abnormal between the gas discharge section of the primary pressure reducing section 12 and the gas input section of the secondary pressure reducing section 13. Since the warning member 19 that can be checked is provided, the primary side pressure reducing section 1
The pipeline can be prevented from being damaged due to abnormal pressure generation from the second to the secondary pressure reducing unit 13, and the warning by the warning member 19 can be confirmed from the outside, so that abnormal pressure is generated. You can avoid having to leave it forever without knowing that you are doing it,
It is possible to expedite the investigation and countermeasures.

Further, according to this embodiment, the gas supply unit 11
In this way, it is possible to alternately select a plurality of cylinders, and to prevent gas from flowing back from unused cylinders to the supplied cylinders when replacing, so that gas supply from unused cylinders can be prevented. The cylinder can be switched without interruption.

In the above embodiment, the case where the existing piping cannot be used has been described. However, the present invention is not limited to this embodiment. For example, as described in the prior art, the present invention is applied to commercial customers such as buildings. It is also possible to use as a target the airtightness test of the pipes. In this case, the pressure and the capacity of the cylinder required for the airtightness test are set, and the gas is supplied from the coupler 50 which is a connection part located on the output side of the supply path in the gas supply control unit 9. In such a case, when the airtight test is completed, only the same gas as the originally supplied gas remains in the pipe, so that the purging operation which has been conventionally performed is unnecessary, and Since the supply can be restarted, the operation and effect of shortening the restoration time to the original gas supply can be obtained.

[0042]

As is apparent from the above description, according to the first and third aspects of the present invention, one of a plurality of high-pressure vessels is selected to take in gas, and the taken-in gas is Although the pressure is reduced to a final pressure corresponding to the pressure at the gas supply destination by a plurality of pressure reducing sections, the pressure is supplied.
Even if the temperature is reduced due to adiabatic expansion during the depressurization process, the temperature is corrected and the member for correcting the gas passage can be prevented from deteriorating due to the temperature. In addition, when the gas pressure at the supply destination is higher than the predetermined pressure, it is possible to prevent the gas from being supplied and prevent the gas from being blown out due to the abnormal pressure, thereby eliminating the cause of ignition. become.

According to the second, fourth to sixth and eighth aspects of the present invention, the temperature drop due to the adiabatic expansion at the time of decompression is corrected only by contacting the atmosphere of the use environment without using an energy source such as a heating source or a power source. Therefore, an energy source causing a fire can be eliminated. In addition, since the structure of the temperature adjustment unit can be reduced in size, the supply control unit can be transported by a cart, so that the temperature control unit can be easily installed in a place where gas supply is required. Further, since the shut-off unit for shutting off the gas when the pressure of the depressurized gas is equal to or higher than the predetermined pressure is operated by the gas itself having reached the predetermined pressure or higher, without adding a special structure. The size of the device used in the gas supply system can be reduced.

According to the seventh aspect of the present invention, the correction of the temperature of the gas, which is reduced when the pressure is reduced, can be executed by the minimum necessary gas passage length, thereby preventing damage to the equipment due to the reduced temperature of the gas. It is possible to reduce the size of the adjustment performed.

According to the ninth to twelfth aspects of the invention, the supply pressure of the gas at the supply destination is monitored, and when the pressure reaches a predetermined pressure or higher, the supply of the gas to the supply destination is automatically stopped. Therefore, the cause of ignition due to the abnormally high pressure gas at the supply destination can be eliminated.

[Brief description of the drawings]

FIG. 1 is a schematic diagram for explaining the concept of a portable gas supply system according to the present invention.

FIG. 2 is an external view of a gas supply device in the system shown in FIG.

FIG. 3 is a block diagram for explaining a configuration of a gas supply control unit included in the gas supply device shown in FIG.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 main pipe 2 service pipe 7 gas supply device 9 gas supply control unit 10 cylinder forming high-pressure vessel 12 primary-side decompression unit 13 secondary-side decompression unit 14 heat exchange unit 15 emergency shutoff unit 17 balance valve 18 shutoff valve 19 warning member 22 Fuse plug 23 Pressure gauge to detect the final reduced pressure

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Kaname 5-1-14-102, Shimotani, Hoya-shi, Tokyo (56) References JP-A-10-2500 (JP, A) (58) Fields surveyed ( Int.Cl. ⁷ , DB name) F17D 1/04 F16K 17/36

Claims (12)

(57) [Claims] 1. A gas supply path in which a gas-filled high-pressure vessel is located on an input side and a connection portion with a gas supply destination is located on an output side, wherein a plurality of the high-pressure vessels are arranged on the input side. Taking in the gas in one high-pressure vessel selected from the plurality of high-pressure vessels, and reducing the pressure of the gas taken in from the high-pressure vessel to the final pressure used at the gas supply destination by a plurality of pressure reducing units. The pressure is reduced, and the gas passing between the pressure reducing sections is introduced into the heat exchange section to perform a temperature correction process. If the pressure of the gas reaching the output side is higher than a predetermined final pressure, the gas is released to the atmosphere or the gas is released. A gas supply system, wherein a flow is blocked. 2. A gas supply path in which a gas-filled high-pressure container is located on an input side and a connection portion with a gas supply destination is located on an output side, between the input side and the output side. A primary-side depressurizing unit and a secondary-side depressurizing unit. A heat exchanging unit is disposed between each of the depressurizing units. The gas exchanging side of the heat exchanging unit has a primary pressure higher than a predetermined pressure. An emergency shutoff unit capable of shutting off gas supply to the side decompression unit is provided, and a gas discharge unit of the secondary side decompression unit is provided with a fuse plug for shutting off gas supply to the connection unit side in an emergency. A gas supply system comprising a gas supply control unit. 3. The gas supply system according to claim 1, wherein the high-pressure vessel arranged on the input side has a pipe line leading to a first-stage depressurizing section of the depressurizing section, and a pipe before the pipes are put together. A gas supply system, characterized in that an on-off valve is arranged in the path so that a path for taking in gas from a high-pressure container can be selected. 4. The gas supply system according to claim 2, wherein said emergency shut-off section is constituted by a pressure-operated valve operated by a gas having a predetermined pressure or higher. 5. The gas supply system according to claim 2, wherein the high-pressure container, the connection unit, and the gas supply control unit are mounted on a cart and can be transported to a supply destination. 6. The gas supply system according to claim 1, wherein the heat exchange section is constituted by a plurality of finned tubes of an atmosphere contact type. 7. The gas supply system according to claim 1, wherein the heat exchange section has a gas passage length set to at least a length of one turn. A gas supply system characterized by: 8. The gas supply system according to claim 1, wherein a plurality of the high-pressure containers can be mounted on the carriage, and a check valve is disposed in a pipe from each of the high-pressure containers to the supplied container. A gas supply system wherein backflow of gas is prevented. 9. The gas supply system according to claim 1, wherein a pressure of the gas reduced to a final pressure is detected in a pipe leading to a connection with a gas supply destination located on the output side. Gas supply system, wherein a gas supply system is disposed. 10. The gas supply system according to claim 1, wherein the pipe before reaching the pressure reducing section for reducing the pressure to the final pressure has a gas flowing through the pipe at a pressure equal to or higher than a predetermined pressure. A gas supply system comprising means for discharging gas to the atmosphere. 11. The gas supply system according to claim 2, wherein an opening / closing valve is provided in the gas discharge section of the secondary pressure reducing section in addition to a fuse plug for shutting off gas supply to the connection section in an emergency. A gas supply system, which is provided. 12. The gas supply system according to claim 2, wherein the gas discharge unit of the secondary-side pressure reducing unit includes a fuse plug,
A gas supply system comprising a relief valve for releasing a gas to the atmosphere when a pressure of a gas reaching a gas discharge portion is equal to or higher than a predetermined pressure, in addition to an on-off valve.