JP2587108B2 - Gas flow leak monitoring system - Google Patents

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial application field) The present invention relates to a gas flow path leakage monitoring system using a gas distribution device utilizing differential pressure.

(Prior Art) For example, a gas supply facility for supplying gas to a collective house such as an apartment is configured as shown in FIG.
In the figure, a gas supply source 1 such as a propane gas cylinder and a gas inlet 3 of an apartment 2 are connected by a gas supply pipe 4, and the gas supply pipe 4 is provided with pressure regulators 5, 6 and a gas meter 7. I have. The gas inlet 3 is provided with, for example, valves 8 and 9 for each floor.
Gas is supplied to the gas consuming facilities 13 by pipes 12 via valves 10 and gas meters 11, respectively, to each of the houses.

On the other hand, for example, a portion of the gas supply pipe 4 close to, for example, the apartment 2 is often buried underground because a passage or the like needs to be provided. The gas supply pipe 4a buried underground in this way may be cracked by a load from the surface of the ground, and there is a risk that gas is leaked from the crack due to the crack caused by corrosion of the piping. Therefore, it is necessary to monitor gas leakage.

Monitoring of this gas leak has conventionally been performed by the following method.

(1) A worker goes to the site every day for about 30 days at night or at night when the gas consumption is low, checks the operation of the gas meter integrator, compares the usage status of consecutive nights, and checks for abnormalities. Find out.

(2) The gas supply is temporarily stopped, the connection portion of the gas supply pipe 4 is disconnected, and pressurized air is introduced to perform an airtight inspection.

(Problems to be Solved by the Invention) However, among the above gas leakage monitoring methods, (1)
As described above, the worker has to go to the site continuously for about 30 days and requires a lot of labor, but it is difficult to detect a minute flow rate with a gas meter that integrates a relatively large flow rate of gas flow. there were. According to the method (2), the gas supply must be temporarily stopped and a part of the pipe must be removed.
The time period during which the inspection can be performed is restricted, and the operation is troublesome. Furthermore, when the gas supply was restarted, if the valves of the consuming equipment in each house were open, a large amount of gas was released, which could lead to an accident.

The present invention has been made in view of the above points, and provides a gas flow path leakage monitoring system using a gas distribution device using a differential pressure having a simple configuration capable of easily performing high-accuracy gas leakage monitoring. The purpose is to do.

[Configuration of the invention]

(Means for Solving the Problems) In order to achieve the above object, an invention according to claim 1 is a gas flow path leakage monitor for monitoring a gas supply pipe connecting a gas supply source and a gas consuming facility for leakage. In the system, a bypass gas flow path that bypasses in parallel with the gas supply pipe is provided, and when the flow rate flowing through the gas supply pipe decreases, the flow path is configured such that gas flows only in the bypass gas flow path. A flow path switching means for switching, a micro leak detection means provided in the bypass gas flow path, the micro leak detection means detects a micro flow rate in the bypass gas flow path, and this micro flow rate is continuously provided for a certain period of time. It is characterized in that it is determined that there is gas leakage when a gas flow rate equal to or higher than a desired gas flow rate is detected.

According to a second aspect of the present invention, in the first aspect of the present invention, the minute leak detecting means is constituted by a microcomputer gas meter, and performs a warning display on the lamp display unit when it is determined that there is a gas leak. It is characterized by becoming.

According to a third aspect of the present invention, in a gas flow path leak monitoring system for monitoring a leak in a gas supply pipe connecting a gas supply source and a gas consuming facility, the gas supply pipe includes one pressure regulator. A bypass gas flow path connecting the inlet side and the outlet side of the one pressure regulator is provided,
The bypass gas flow path is provided with another pressure regulator having a higher regulation pressure than the one pressure regulator, and a minute leak detecting means.

The invention according to claim 4 is the invention according to claim 3, wherein one pressure regulator and the other pressure regulator are integrally formed.

(Operation) According to the first aspect of the invention, when the flow rate in the gas supply pipe is small and the pressure in the pipe is high, the flow path is switched, and the gas flows only in the bypass gas flow path. Therefore, for example, when gas consumption almost stops at night or late at night, if there is a gas leak in the gas supply pipe, this gas flows only through the bypass gas flow path, and a minute leak detection means is provided in this. This is detected, integrated, and monitored by a minute leak detection function. If the minute flow rate is continuously detected for a predetermined gas period or more at a desired gas flow rate, it can be determined that there is a gas leak.

Therefore, the gas flow in this time zone can be detected by the micro leak detection means using the time zone during which gas consumption almost stops, such as at night or late at night.

According to the second aspect of the present invention, the same operation as the first aspect of the invention is provided, and the micro-leakage detecting means is constituted by the microcomputer gas meter. Therefore, the flow rate can be accurately integrated, and the gas leakage can be reliably performed. Can be detected.

According to the third aspect of the present invention, since the adjustment pressure of the other pressure regulator is set higher than that of the one pressure regulator, when the flow rate flowing through the gas supply pipe is small and the pressure in the pipe increases, the pressure of the one pressure regulator increases. The regulator is closed and the gas is regulated by the other pressure regulator only and flows only in the bypass gas flow path. Therefore, for example, when gas consumption almost stops at night or late at night, if there is a gas leak in the gas supply pipe, this gas flows through the bypass gas flow path and is detected by the minute leak detecting means.

When a large amount of gas flows through the gas supply pipe as in the case of normal gas use, the supply pressure decreases and one of the pressure regulators operates, and the gas flows through one and the other pressure regulators. Feeding takes place.

Therefore, by utilizing the time zone during which gas consumption almost stops, such as at night or late at night, and monitoring the gas flow in this time zone by the micro leak detection means, accurately and easily without stopping the gas supply. The presence or absence of gas leakage from the gas supply pipe can be confirmed.

According to the fourth aspect of the invention, the same effect as that of the third aspect of the invention can be obtained, and the entire apparatus can be significantly reduced in size.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

1 to 4 show an embodiment of the present invention. First
FIG. 2 is an arrangement diagram of the system configuration of this embodiment, and FIG. 2 is an enlarged view of a main part of FIG. In the figure, the same or equivalent parts as those of the conventional example shown in FIG. 9 are denoted by the same reference numerals, and description thereof will be omitted.

The gas supply pipe 4b between the original pressure regulator 5 on the propane gas cylinder 1 side serving as a gas supply source and the original gas meter 7 for integrating the amount of gas supplied to the entire apartment 2 has one pressure regulator, ie, the first pressure. A regulator 6 is provided, and a gas supply pipe 4b is provided with a bypass gas flow path 14 connecting the inlet side and the outlet side of the first pressure regulator 6. A valve 15, the other pressure regulator, that is, a second pressure regulator 16, a micro-leakage detecting means in this embodiment, a microcomputer gas meter 17 (hereinafter referred to as “M meter 17”) and a valve 18 are sequentially provided from the inlet side. Is provided. Then, the adjustment pressure of the second pressure regulator 16 is set higher than the adjustment pressure of the first pressure regulator 6. For example, when adjusting the pressure of the first pressure regulator 6 is set to 280 mm H ₂ O, adjust the pressure of the second pressure regulator 16 so as to set to about 300 mm H ₂ O. In addition, the M meter 17 can accurately accumulate a minute flow rate, for example, a flow rate of about 3 / hr, and monitor by a minute leak detection function. If a leak of 3 / hr or more is detected for 30 consecutive days, a gas leak is detected. Judgment is made, and a lamp display on the M meter is used.

Next, the operation of the present embodiment will be described. The detection of minute leakage of gas in the gas supply pipe 4 is performed using a time zone in which gas consumption almost stops at night or at midnight. First valve 1
Open 5,18, introducing a gas into the bypass gas flow passage 14, the second pressure regulator 16 adjusts pressure of about 20 mm H ₂ than the regulated pressure of the first pressure regulator 6 O to 30 mm H ₂ O Set higher. At this time, if the gas does not leak from the gas supply pipe 4, the gas hardly flows through the gas supply pipe 4 and the bypass gas flow path 14, the supply pressure rises, and the first and second pressure regulators
6, 16 are in the closed state.

If gas leaks from the gas supply pipe 4, the gas supply pipe 4
Although a small flow rate of gas continuously flows through the inside, the first pressure regulator 6 is closed due to a low regulated pressure, and the gas is
The pressure is regulated only by the pressure regulator 16 of the bypass gas flow path.
It flows only within 14. Since this gas flow rate is accurately measured by the M meter 17 constituting the micro leak detecting means, the gas leak can be detected reliably.

On the other hand, when a large amount of gas flows through the gas supply pipe 4 during normal gas use, the supply pressure drops below the regulated pressure of the first pressure regulator 6, and the first pressure regulator 6 is activated. The gas then flows through the gas supply pipe 4 and the bypass gas passage 14 via the first and second pressure regulators 6 and 16, respectively. At this time, the valve provided in the bypass gas flow path 14
The gas may be flowed through only the gas supply pipe 4b by closing the 15,15.

According to this embodiment, if there is a gas leak in the gas supply pipe 4 during the time period when gas consumption almost stops at night or at midnight,
The gas flows only in the bypass gas flow path 14 due to the differential pressure between the adjusted pressures of the first and second pressure regulators 6 and 16, and the leak can be accurately detected by the M meter 17 constituting the micro leak detecting means. it can. Therefore, while it is possible to easily monitor the minute leak of the gas supply pipe 4 without stopping the gas supply at all times, it is necessary for the worker to go directly to the site every night and check the gas meter by the minute leak detecting function of the M meter 17. Without much labor.

In the above embodiment, the first and second pressure regulators 6 and 16 are formed separately, and the gas supply pipe 4b and the gas bypass passage are respectively provided.
Although the description has been given of the case where the pressure regulators are attached to 14, the pressure regulators 6 and 16 may be integrally formed as shown in FIGS. Hereinafter, the structure of the integrated pressure regulator will be described.

In the figure, an inlet pipe 21 connected to the original pressure regulator 5 shown in FIG. 1 is mounted at one end of a main body case 20, and a first pressure regulating valve constituting a first pressure regulating valve is provided inside the main body case 20. It is branched into a decompression chamber 22a and a second decompression chamber 22b constituting a second pressure regulating valve, and communicates with the inlet pipe 21 respectively. A pair of outlet ports 23a and 23b are formed at the other end of the main body case 20, and communicate with the decompression chambers 22a and 22b, respectively. Since the structures of the first and second pressure regulators are the same, the first pressure regulator will be described, and the same parts of the second pressure regulator will be denoted by the same reference numerals and the description thereof will be omitted. Omitted.

An opening 24a is provided on the upper surface of the first decompression chamber 20a of the main body case 20.
Are formed, and a cover 25a is fixed to the opening 24a. A peripheral edge of a diaphragm 26a is fixed between the main body case 20 and the cover 25a, and the diaphragm 26a hermetically partitions an atmospheric pressure chamber 27a on the cover 25a side and a decompression chamber 22a in the case 20. . Diaphragm 26a
An operating rod 28a is vertically provided at the center of the cover, and a spring is provided between the diaphragm 26a and the cover 25a.
29a is interposed and constantly biases the diaphragm 26a downward. An operating end of an operating lever 30a is slidably crossed and engaged with a lower portion of the operating rod 28a. The operation lever 30a is rotatably supported in the case 20 via a support shaft 31a, and its operation end is provided on a valve body 33a facing a tip nozzle portion 32a on one side of the branch of the inlet pipe 21. It is engaged via the action pin 34a. The atmospheric pressure chamber of the operating rod 28a
A nut (not shown) is screwed into the tip protruding into the inside 27a, and a safety valve adjustment spring 35a is interposed between the nut and the center of the diaphragm 26a.
8a and the safety valve element 36a formed integrally with the diaphragm 2
It is urged in the direction of contact with the lower surface of 6a. Incidentally, reference numeral 37a in the drawing denotes a spring receiver screwed to the cover 25a,
Reference numeral 38a is a cap attached to the upper end of the cover 25a.

In the pressure regulator configured as described above, the pressure reducing chamber
When the pressure in 22a rises, diaphragm 26a springs
Overcoming the biasing force of 29a, displacing to the atmospheric pressure chamber 27a side, pulling up the operating rod 28a, turning the operation lever 30a counterclockwise around the support shaft 31a, and bringing the valve body 33a close to the nozzle portion 32a. By reducing the inflow of gas, the gas pressure in the decompression chamber 22a is reduced. In this way, the gas pressure in the decompression chamber 22a is kept substantially constant in accordance with the urging force of the spring 29a.
Also, when the gas pressure in the decompression chamber 22a rises abnormally, the safety valve adjustment spring 35a is compressed via the diaphragm 26a,
The valve element 36a of the safety valve separates from the lower surface of the diaphragm 26a, and the gas blows out into the cover 25a, thereby preventing an abnormal increase in gas pressure in the pipeline.

Although the first pressure regulator has been described above, the configuration and operation of the second pressure regulator are the same.
However, as described above, the adjustment pressure of the second pressure regulator is
Approximately 20mm H ₂ O to 30mm H ₂ O
The biasing force of the spring 29b is adjusted so as to be higher.

With the integrated pressure regulator as described above, the same operation and effect as in the case of the separate pressure regulator can be obtained, and the pressure regulator can be downsized, so that the equipment space can be reduced.

The outlets 23a and 23b of the pressure regulator shown in FIGS. 3 and 4 are provided in parallel directions.
The direction may be a right angle as shown in FIG. 5 and FIG. 6, and a pair of pressure regulators 6 and 16 are connected in series as shown in FIG. 7 and FIG. Provide input port 21,
Outlet ports 23a and 23b may be provided on the opposite side.
In this case, the outlet port 23b provided in the pressure regulator 16 may be in both directions, one of which may be connected to the bypass gas flow path 14 and the other may be closed according to the condition of the piping. Each of the pressure regulators shown in FIGS. 5 to 8 is appropriately selected and used depending on the condition of the piping.

〔The invention's effect〕

As described above, according to the first aspect of the present invention,
When the flow rate flowing through the gas supply pipe is small and the pressure in the pipe increases, the flow path is switched, and the gas flows only through the bypass gas flow path. Therefore, for example, when gas consumption almost stops at night or at midnight, if there is a gas leak in the gas supply pipe, this gas flows only in the bypass gas flow path, and a minute leak detection means is provided in this. Is detected and integrated, and monitored by a minute leak detection function. When the minute flow rate is continuously detected for a predetermined gas period or more at a desired gas flow rate, it can be determined that there is a gas leak.

Therefore, the gas flow in this time zone can be detected by the micro leak detection means using the time zone during which gas consumption almost stops, such as at night or late at night.

According to the second aspect of the present invention, the same operation and effect as those of the first aspect of the present invention can be obtained, and the micro-leakage detecting means is constituted by the microcomputer gas meter. Can be detected.

According to the third aspect of the present invention, since the adjustment pressure of the other pressure regulator is set higher than that of the one pressure regulator, when the flow rate flowing through the gas supply pipe is small and the pressure in the pipe increases, the pressure of the one pressure regulator increases. The regulator is closed and the gas is regulated by the other pressure regulator only and flows only in the bypass gas flow path. Therefore, for example, when gas consumption almost stops at night or late at night, if there is a gas leak in the gas supply pipe, this gas flows through the bypass gas flow path, and this is detected by the micro leak detection means, so that the gas supply pipe is Gas leaks,
The detection can be performed easily and reliably without stopping the gas supply.

According to the invention according to claim 4, the entire device can be significantly reduced in size.

[Brief description of the drawings]

FIG. 1 is a layout diagram showing a system configuration according to an embodiment of the present invention, FIG. 2 is an enlarged view of a main part of FIG. 1, and FIG. 3 is a longitudinal section showing an embodiment of a pressure regulator used in the present invention. 4, FIG. 4 is a plan view of the same, FIG. 5 and FIG. 7 are front views each showing another embodiment of the pressure regulator used in the present invention,
6 and 8 are plan views of FIGS. 5 and 7, respectively, and FIG. 9 is a layout view showing a conventional gas supply facility. DESCRIPTION OF SYMBOLS 1 ... Gas supply source 4 ... Gas supply pipe 4a ... Buried part 6 ... First pressure regulator 13 ... Gas consuming equipment 14 ... Bypass gas flow path 16 ... Second pressure regulator 17 ... … Gas meter (M meter)

 ──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor, Nobuhiro Hikosaka 1370, Koyasu-cho, Hamamatsu-shi, Shizuoka Prefecture Inside Yazaki Corporation (56) References , A)

Claims (4)

(57) [Claims] 1. A gas flow path leakage monitoring system for monitoring leakage in a gas supply pipe connecting a gas supply source and gas consuming equipment, wherein a bypass gas flow path is provided in parallel with the gas supply pipe. A flow switching unit that switches a flow path so that gas flows only in the bypass gas flow path when a flow rate flowing through the gas supply pipe is reduced, and a micro leak detection means is provided in the bypass gas flow path. The micro-leakage detecting means detects a micro-flow rate in the bypass gas flow path, and determines that there is a gas leak when the micro-flow rate is continuously detected at a desired gas flow rate over a certain period of time. Gas flow leak monitoring system. 2. The micro-leakage detecting means is constituted by a microcomputer gas meter, and displays a warning on a lamp display when it is determined that there is a gas leak. 1) The gas flow channel leakage monitoring system according to 1). 3. A gas flow path leak monitoring system for monitoring a leak in a gas supply pipe connecting a gas supply source and a gas consuming facility, wherein the gas supply pipe is provided with one pressure regulator and one of the pressure regulators. A bypass gas flow path that connects the inlet side and the outlet side of the pressure regulator is provided, and the bypass gas flow path is provided with another pressure regulator having a higher regulated pressure than the one pressure regulator, By providing the micro leak detecting means, when the inside of the gas supply pipe is at a low flow rate, the gas flows only into the bypass gas flow path, and the micro leak detecting means detects the micro flow rate in the bypass gas flow path. Road leak monitoring system. 4. The gas flow path leakage monitoring system according to claim 3, wherein one pressure regulator and the other pressure regulator are integrally formed.