JP2009276235A - Gas shut-off device, and gas shut-off system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gas shut-off device and a gas shut-off system capable of easily and accurately performing investigation work of gas leakage. <P>SOLUTION: The gas shut-off device 1 includes: a pressure sensor 6 for measuring the value of pressure in gas piping; a drive control means 11a for positioning a valve element to an arbitrarily determined pressure measurement position for each pressure information request signal by a drive means according to a pressure information request signal input from the outside; a pressure value measurement means 11b for measuring a pressure value by the pressure sensor 6 after the valve element is positioned at a pressure measurement position by the drive control means 11a; and a pressure information output means 11c to output a pressure information signal, based on the pressure value measured by the pressure value measurement means 11b. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a gas shut-off device and a gas shut-off system including the gas shut-off device, and more specifically, a gas shut-off device including a gas shut-off valve that shuts off gas supply when an abnormality such as gas leakage occurs. It relates to a shut-off system.

  The gas shut-off valve is a safety device incorporated in the gas pipe in order to shut off the gas flowing through the gas pipe when, for example, an abnormality such as a gas leak is detected.

  As the above-described gas cutoff valve, for example, a gas cutoff valve proposed in Patent Document 1 is known. As shown in FIG. 6, the gas cutoff valve 700 includes a housing 702 and a cutoff valve unit 701. The housing 702 includes a tube body 703 and a mounting seat 705 for mounting the shut-off valve unit 701. The tube body 703 has flow path spaces 707a and 707b and through holes 709 that communicate with the flow path spaces 707a and 707b. The shut-off valve unit 701 includes a valve body 726 that communicates or shuts off the flow path spaces 707a and 707b by coming into contact with and separating from the through hole 709, a spring 728 and a motor 729 for driving the valve body 726, and a flow path space 707b. A semiconductor pressure sensor 731 for measuring the pressure of the valve body, a valve operation detection photosensor 732 for detecting the operation of the valve body 726, an operation indicator lamp 735, and a circuit board 736 for operating the gas shut-off valve. , Attached to a mounting seat 705 of the housing 702. Further, the valve body 726 is separated from the through hole 709 in the normal state, that is, the gas shut-off valve 700 is opened.

  The gas shut-off valve 700 constantly measures the pressure value in the flow path space 707b connected to the downstream side of the gas pipe by the pressure sensor 731. For example, the measured pressure value is set in advance due to gas leakage or the like. When the allowable range is exceeded, the valve body 726 is driven so as to be joined to the through hole 709 (that is, shut-off control), the flow passage spaces 707a and 707b are shut off, and the gas supply downstream of the gas pipe is stopped. Then, the display of the operation indicator lamp 735 is changed to notify the user that a gas leak has been detected.

  However, in the investigation work carried out when a gas leak occurs in the gas pipe, it is necessary to check the pressure value in the gas pipe in order to check the degree of gas leak and identify the location of the gas leak. Although the shutoff valve 700 is provided with a pressure sensor 731, the measured value is used only for the shutoff control described above, and the measured pressure value cannot be directly confirmed. Therefore, in order for the operator to check the pressure value in the gas pipe, for example, the gas shut-off valve 700 is once removed from the gas pipe and an investigation pressure sensor is disposed in the gas pipe. It is necessary to reattach the gas pipe to the gas pipe and supply the gas again to measure the pressure value in the gas pipe. For the installation of the pressure sensor for investigation and the removal / attachment of the gas shut-off valve 700, There was a problem that a long time was required for the investigation work in order to avoid the new gas leakage caused by the problem.

As a solution to this problem, for example, in the gas shutoff valve 700, a display unit for displaying the pressure value and a display control means for displaying the value measured by the pressure sensor 731 on the display unit are added. According to this configuration, it is not necessary to install a pressure sensor for investigation, so that the time required for investigation work for gas leakage can be shortened.
JP 2007-270957 A

  However, in the investigation work of the gas leak, the location of the gas leak can be specified by positioning the valve body at a predetermined pressure measurement position and measuring the pressure value (for example, positioning the valve body so that the valve is closed). By measuring the pressure value on the downstream side of the gas piping, if a gas leak is detected in this state, it can be determined that the gas leak location is on the downstream side. If no gas leak is detected, the gas leak location is on the upstream side. However, in the gas shut-off valve 700 described above, the display unit for displaying the pressure value and the display control means for displaying the value measured by the pressure sensor 731 on the display unit are added. In the configuration described above, since the operator needs to manually position the valve body at the pressure measurement position, there is a risk that the operation becomes complicated and the pressure measurement position may be mistaken due to an operation error. In particular, when there are a plurality of pressure measurement positions of the valve body, the operation of positioning the valve body at each pressure measurement position and measuring the pressure value is repeated, which makes the work more complicated and easily causes an operation error. And, if the pressure measurement position is wrong, an accurate pressure value cannot be measured, so that the gas leak investigation result becomes inaccurate and the investigation reliability is lowered.

  The present invention aims to solve the above problems. That is, an object of the present invention is to provide a gas shut-off device and a gas shut-off system capable of easily and accurately performing a gas leak investigation work.

  In order to achieve the above object, the invention described in claim 1 is directed to a flow path connected to a gas pipe, a valve body incorporated in the flow path and opening and closing the flow path, and driving the valve body. A gas shut-off valve device having a pressure sensor for measuring a pressure value in the gas pipe and a pressure information request signal input from the outside in response to a pressure information request signal input from the outside. Drive control means positioned at a pressure measurement position arbitrarily determined for each information request signal, and pressure at which the pressure sensor measures the pressure value after the valve body is positioned at the pressure measurement position by the drive control means A gas shut-off device comprising: a value measuring means; and a pressure information output means for outputting a pressure information signal based on the pressure value measured by the pressure value measuring means.

  The invention described in claim 2 is the pressure value change measuring means for measuring a change in the pressure value measured by the pressure value measuring means within a predetermined time in the invention described in claim 1, and the pressure value. A gas leakage degree determining means for determining the degree of gas leakage based on a change in the pressure value measured by a change measuring means, and the pressure information output means is determined by the gas leakage degree determining means. This means is a means for outputting a gas leakage degree information signal corresponding to the degree of gas leakage.

  The invention described in claim 3 includes the gas shut-off device described in claim 1 or 2, and an operation unit for inputting the pressure information request signal to the gas shut-off device, and the operation unit Is configured to display information corresponding to the pressure information signal or the gas leakage degree information signal output from the pressure information output means of the gas shut-off device in response to the input pressure information request signal. This is a gas shut-off system.

  According to the invention described in claim 1, after positioning the valve body at the pressure measurement position corresponding to the pressure information request signal input to the gas shut-off device, the pressure value in the gas pipe is measured and the value is obtained. Since it can output, the operation | work which positions a valve body in a pressure measurement position manually becomes unnecessary, Therefore The investigation operation | work accompanying a gas leak can be performed easily and correctly.

  According to the second aspect of the present invention, it is possible to measure the change in the pressure value in the gas pipe within a predetermined time and output the information indicating the degree of gas leakage according to the change. An operation for measuring a change in pressure value in the gas pipe is not required, and therefore, an investigation operation associated with a gas leak can be performed more easily and accurately.

  According to the third aspect of the present invention, the gas cutoff device and the pressure information signal and / or the gas leakage degree information signal output from the gas cutoff device after transmitting the pressure information request signal to the gas cutoff device are supported. Since it has an operation unit that displays information, easy operation and clear information display by the operation unit can be performed without connecting a survey device such as a personal computer. It can be done easily and accurately. In addition, for example, the gas shut-off device and the operation unit can be disposed at a distance, such as the gas shut-off device disposed outdoors and the operation unit disposed indoors. It becomes possible, and the investigation work accompanying gas leakage can be easily performed.

(First embodiment)
Hereinafter, the gas cutoff system which shows the 1st Embodiment of this invention is demonstrated with reference to FIGS. 1-3.

  As shown in FIG. 1, the gas shut-off system 51 includes an operation unit 2 and a gas shut-off device 1.

  The operation unit 2 includes operation buttons 21a, 21b, and 21c, a display unit 22, and a microcomputer (not shown).

  Each of the operation buttons 21a, 21b, and 21c is a well-known push button switch to which an operation input for controlling the gas cutoff device 1 is input. The display unit 22 is a small liquid crystal display device for displaying the operating state of the gas cutoff device.

  The microcomputer provided in the operation unit 2 is a well-known small computer suitable for an embedded device, to which operation buttons 21a, 21b, and 21c and a display unit 22 are connected. The microcomputer has a communication serial interface, and transmits and receives various control signals to and from the gas cutoff device 1. For example, the microcomputer responds to the operation of the operation buttons 21a, 21b, and 21c. A control signal is transmitted to the gas cutoff device 1, and various types of information corresponding to the control signal received from the gas cutoff device 1 are displayed on the display unit 22.

  In the operation unit 2, as a control signal transmitted from the operation unit 2 to the gas cutoff device 1, there is a pressure information request signal for requesting a pressure value of the gas pipe. Further, the pressure information request signal includes, as its type, an inspection pressure request signal for requesting an inspection pressure value for specifying a gas leak location, and a normal pressure request signal for requesting a pressure value in the current state. . The inspection pressure request signal and the normal pressure request signal are signals for analysis. For example, when the operation button 21a is pressed while the operation button 21c is pressed, the inspection pressure request signal is transmitted. A normal pressure request signal is transmitted by pressing for a few seconds.

  As a control signal received by the operation unit 2 from the gas cutoff device 1, there is a pressure information signal indicating the measured pressure value. This pressure information signal includes the pressure value of the gas pipe measured in response to the inspection pressure request signal or the normal pressure request signal, and the operation unit 2 is included when receiving this pressure information signal. The pressure value is displayed on the display unit 22.

  The gas cutoff device 1 includes a gas flow path 3, a valve 4, a driving means 5, a pressure sensor 6, and a microcomputer 10.

  The gas flow path 3 corresponds to the flow path described in the claims, and an upstream gas pipe 31a connected to a gas supply section (not shown) and a downstream gas connected to a gas demand section (not shown). It is a pipe line connecting the pipe 31b.

  The valve 4 corresponds to the valve body described in the claims, and is incorporated into the gas flow path 3 and is made conductive (open state) and shut off (closed state), whereby the gas flow path 3 3, that is, the flow of gas flowing through the gas pipe is controlled.

  The drive means 5 is a drive device such as an electromagnet or a motor for opening and closing the valve 4. The driving means 5 is combined with the valve 4, for example, a solenoid valve that opens and closes the disc-shaped valve 4 attached to the movable iron piece by driving the movable iron piece (plunger) with an electromagnet, or a spherical valve. A (ball valve) 4 is configured as a motor valve that opens and closes by a motor via a plurality of gears. In the present embodiment, these configurations are arbitrary as long as the gas flow path 3 can be opened and closed.

  The pressure sensor 6 is a well-known semiconductor pressure sensor including a silicon chip whose resistance value changes due to strain on a diaphragm. The pressure sensor 6 is disposed closer to the downstream side of the gas flow path 3 than the valve 4 so that the pressure value of the downstream side gas pipe 31b can be measured when the gas flow path 3 is closed.

  The microcomputer 10 (hereinafter referred to as MPU 10) is a well-known small computer suitable for an embedded device, and the MPU 10 is a central processing unit that performs various processes and controls according to a predetermined program as shown in FIG. A device (CPU) 11, a ROM 12 that is a read-only memory storing a program and control data for the CPU 11, and a readable / writable memory that stores various data and has an area necessary for processing operations of the CPU 11 The RAM 13, the driving means 5, and the pressure sensor 6, and an I / O unit 14 for transmitting / receiving control information to / from them are provided. Further, the I / O unit 14 includes a communication serial interface for connection to the operation unit 2. Using this communication serial interface, the I / O unit 14 receives (inputs) a pressure information request signal from the operation unit 2, A pressure information signal and a gas leakage degree information signal are transmitted (output) to the operation unit 2.

  As shown in FIG. 2, based on the program stored in the ROM 12, the CPU 11 (1) in response to a pressure information request signal (ie, inspection pressure request signal, normal pressure request signal) input from the operation unit 2. Drive control means 11a for positioning the valve 4 at a pressure measurement position arbitrarily determined for each pressure information request signal by the drive means 5, and (2) pressure after the valve 4 is positioned at the pressure measurement position by the drive control means 11a. Pressure value measuring means 11b for measuring the pressure value of the downstream gas pipe 31b by the sensor 6, and (3) a pressure information signal based on the pressure value measured by the pressure value measuring means 11b via the I / O unit 14 through the operation unit 2 It functions as the pressure information output means 11c that outputs to The pressure measurement position corresponding to the inspection pressure request signal is the valve 4 fully closed position (that is, the gas flow path 3 is fully closed), and the pressure measurement position corresponding to the normal pressure request signal is the valve 4 current position (that is, The gas flow path 3 is in the current state).

  Next, an example of the pressure value measurement process according to the present invention executed by the CPU 11 described above will be described with reference to the flowchart shown in FIG.

  When the gas shut-off device 1 is turned on, detection processing for detecting gas leakage by a gas leakage detection means (not shown) is performed after predetermined initialization processing such as positioning the valve 4 in the fully open position to make it fully open. Migrate to Thereafter, when a gas leak is detected, a control signal indicating the occurrence of gas leak is transmitted to the operation unit 2, and then the processing of the CPU 11 proceeds to step S110.

  In step S110, it is determined whether the pressure information request signal has been received from the operation unit 2 via the I / O unit 14, and when the pressure information request signal has been received, the process proceeds to step S120 to confirm the type (step S120). If the pressure information request signal has not been received, step S110 is repeated until it is received (N in S110).

  In step S120, the type of the pressure information request signal received in step S110 is confirmed. If the type is the test pressure request signal, the process proceeds to step S130 to move the valve 4 to a position corresponding to the test pressure request signal ( If it is not the inspection pressure request signal (that is, the type is the normal pressure request signal), the process proceeds to step S140 to measure the pressure value while keeping the position of the valve 4 as it is (N in S120). ).

  In step S130, the drive unit 5 is driven so that the valve 4 is positioned at the fully closed position (that is, the pressure measurement position corresponding to the inspection pressure request signal). Then, after detecting that the valve 4 is in the fully closed position by a position sensor (not shown), the process proceeds to step S140.

  In step S140, the pressure value of the downstream gas pipe 31b is measured by the pressure sensor 6. At this time, if the valve 4 is in the fully closed position, the pressure value of the downstream gas pipe 31b is measured. If the valve 4 is in the open position, the upstream gas pipe 31a and the downstream gas pipe 31b are measured. Will be measured. And after measuring a pressure value, it progresses to step S150.

  In step S150, a pressure information signal storing the pressure value measured in step S140 is transmitted to the operation unit 2 via the I / O unit 14.

  The above-described steps S120 and S130 correspond to the drive control means described in the claims, step S140 corresponds to the pressure value measuring means, and step S150 corresponds to the pressure information output means.

  Next, an example of the pressure value measuring operation according to the present invention in the gas cutoff system 51 will be described.

  In the gas shut-off system 51, in order to identify a gas leak location, when the operator depresses the operation button 21a while depressing the operation button 21c, the valve 4 is moved to the fully closed position accordingly, and the gas flow path 3 is completely closed. The pressure value in the downstream gas pipe 31b is measured and the measured pressure value is displayed on the display unit 22. Then, the operator determines from the pressure value displayed on the display unit 22 whether the gas leak is occurring in the downstream gas pipe 31b or the upstream gas pipe 31a.

  Further, in the gas shut-off system 51, in order to confirm the current gas leakage state, when the operator presses the operation button 21c for a few seconds, the valve 4 is left as it is and the pressure value of the downstream gas pipe 31b remains unchanged. Then, the measured pressure value is displayed on the display unit 22. Then, the operator determines the state of gas leakage from the pressure value displayed on the display unit 22.

  As described above, according to the present invention, after the valve 4 is positioned at the pressure measurement position corresponding to the pressure information request signal (that is, the inspection pressure request signal, the normal pressure request signal) input to the gas shut-off device 1, the downstream side Since the pressure value in the gas pipe 31b can be measured and the value can be output, there is no need to manually position the valve 4 at the pressure measurement position. Therefore, the investigation work associated with the gas leakage is easily and accurately performed. be able to.

  Further, the gas shutoff device 1 and information corresponding to the pressure information signal output from the gas shutoff device 1 after transmitting the pressure information request signal to the gas shutoff device 1 (that is, the pressure value in the downstream gas pipe 31b) are displayed. Operation unit 2 that can perform easy operation and clear information display using the operation unit 2 without connecting a survey device such as a personal computer. And it can be done accurately. Further, for example, the gas shut-off device 1 and the operation unit 2 can be disposed at a distance such as the gas shut-off device 1 being disposed outdoors and the operation unit 2 being disposed indoors. Work by operation becomes possible, and investigation work accompanying gas leakage can be easily performed.

(Second Embodiment)
Hereinafter, a gas shut-off system showing a second embodiment of the present invention will be described with reference to FIG. 1, FIG. 2, FIG. 4, and FIG.

  As shown in FIG. 1, the gas cutoff system 52 includes an operation unit 2 and a gas cutoff device 1. Note that the same components as those in the first embodiment described above are denoted by the same reference numerals and description thereof is omitted.

  In the operation unit 2, there is a pressure information request signal for requesting pressure information of the gas pipe as a control signal transmitted from the operation unit 2 to the gas cutoff device 1. Further, the pressure information request signal includes, as types, a gas leak level request signal for requesting measurement of the gas leak level and a normal pressure request signal for requesting a pressure value in the current state. The gas leak level request signal and the normal pressure request signal are signals for analysis. For example, when the operation button 21a is pressed while the operation button 21c is pressed, the gas leak level request signal is transmitted. A normal pressure request signal is transmitted by pressing and holding 21c for several seconds.

  Control signals received by the operation unit 2 from the gas shut-off device 1 include a gas leak level information signal indicating the level of gas leak and a pressure information signal indicating the measured pressure value. The gas leakage degree information signal includes information indicating the degree of gas leakage based on a change in pressure value within a predetermined time (for example, a numerical value corresponding to the gas leakage state), and the pressure information signal includes The pressure value of the gas pipe measured in response to the inspection pressure request signal or the normal pressure request signal is included, and when the operation unit 2 receives the gas leakage degree information signal or the pressure information signal, it is included in these information signals. Information (for example, pressure value) or a message (for example, “no leak”, “large gas leak”, “during gas leak”, “small gas leak”, etc.) is displayed on the display unit 22.

  As shown in FIG. 2, the CPU 11 of the gas shut-off device 1 performs (1) a pressure information request signal (that is, a gas leak level request signal, a normal pressure) input from the operation unit 2 based on a program stored in the ROM 12. Drive control means 11a for positioning the valve 4 at a pressure measurement position arbitrarily determined for each pressure information request signal by the drive means 5 according to the request signal), and (2) the valve 4 is brought to the pressure measurement position by the drive control means 11a. After being positioned, the pressure value measuring means 11b for measuring the pressure value of the downstream gas pipe 31b by the pressure sensor 6, and (3) the pressure information signal based on the pressure value measured by the pressure value measuring means 11b is sent to the I / O unit 14 Pressure information output means 11c for outputting to the operation unit 2 via the (4) change in the pressure value measured by the pressure value measuring means within a predetermined time. It functions as a pressure value change measuring means 11d to be determined, and (5) a gas leak degree judging means 11e for judging the degree of gas leak based on the change in the pressure value measured by the pressure value change measuring means 11d. . Further, the CPU 11 also functions as a means for outputting a gas leakage degree information signal corresponding to the degree of gas leakage determined by the gas leakage degree determination means 11e with respect to the pressure information output means 11c. The pressure measurement position corresponding to the gas leakage degree request signal is the valve 4 fully closed position (that is, the gas flow path 3 is fully closed), and the pressure measurement position corresponding to the normal pressure request signal is the valve 4 current position (that is, the valve 4 fully closed position). The gas flow path 3 is in the current state).

  Further, the ROM 12 includes, as control data, a measurement period (time interval) X (for example, 60 seconds) for measuring a pressure value by the pressure sensor 6, a gas leak reference value ΔP (for example, 10 Pa) used for gas leak determination, The comparison number upper limit value n (for example, 10 times) between the difference between the pressure values and the gas leakage reference value ΔP, and the first comparison number reference value J (for example, 3 times) for determining the degree of gas leakage “large” The second comparison number reference value K (for example, 5 times) for determining the degree of gas leakage “medium” is stored. The RAM 13 is provided with a gas leakage degree information area for storing gas leakage degree information indicating the degree of gas leakage. For example, “0” indicates “no leak”, “1” indicates “large gas leak”, “2” indicates “gas leaking”, and “3” indicates “small gas leak”. As an initial value, 0 is stored.

  Next, an example of the gas leakage degree measurement process according to the present invention executed by the CPU 11 will be described with reference to the flowcharts shown in FIGS. In addition, the same code | symbol is attached | subjected to the step which performs the same process as 1st Embodiment mentioned above, and the description is abbreviate | omitted. In the present embodiment, steps S110 and S130 proceed to steps S121 and S200, respectively, after the processing ends.

  In step S121, the type of the pressure information request signal received in step S110 is confirmed. If the type is a gas leak level request signal, the process proceeds to step S130 to move the valve 4 to a position corresponding to the gas leak level request signal. Proceed (Y in S121), and if it is not a gas leak level request signal (ie, the type is a normal pressure request signal), proceed to step S140 to measure the pressure value while keeping the position of the valve 4 as it is ( N at S120).

  In step S200, the following pressure value change measurement process is performed.

  In step S210, after the first pressure value P1 is measured by the pressure sensor 6, time measurement by the timer T is started. Then, the process proceeds to step S220.

  In step S220, the process waits until the time elapsed after the pressure value is measured by the pressure sensor 6 (that is, the timer T) passes the period X stored in the ROM 12 (N in S220), and the predetermined period X Then, the process proceeds to step S230 (Y in S220).

  In step S230, after measuring the y-th pressure value Py (y ≧ 2) which is the pressure value after the second time, the timer T is reset and the time measurement is started again. Then, the process proceeds to step S240.

  In step S240, the difference between the first pressure value P1 and the yth pressure value Py is compared with the gas leak reference value ΔP stored in the ROM 12, and if the difference is less than or equal to the gas leak reference value ΔP, the process proceeds to step S250. The process proceeds (Y in S240), and if the difference exceeds the gas leak reference value ΔP, the process proceeds to step S270 to determine the degree of gas leak (N in S240).

  In step S250, the number of comparisons between the difference between the first pressure value P1 and the yth pressure value Py described above with the gas leakage reference value ΔP stored in the ROM 12 is counted, and the number of comparisons is stored in the ROM 12. When the upper limit value n is exceeded, it is determined that no gas leak has been detected, and the process proceeds to step S260 (Y in S250). When the number of times is smaller than the comparison number upper limit value n, a step is performed to measure the pressure value again. The process proceeds to S220 (N in S250).

  In step S260, a value “0” indicating “no leak” is stored in the gas leak degree information area provided in the RAM 13, assuming that there is no gas leak. Then, the process proceeds to step S151 in FIG.

  In step S270, it is determined how many times the comparison has been performed until the difference between the first pressure value P1 and the y-th pressure value Py exceeds the gas leakage reference value ΔP. If it is less than the first comparison number reference value J, it is determined that the degree of gas leakage is large, and the process proceeds to step S280 (Y in S270), and if it is equal to or greater than the first comparison number reference value J, the process proceeds to step S290 (N in S270).

  In step S280, assuming that the degree of gas leakage is large, the value “1” indicating “large gas leakage” is stored in the gas leakage degree information area provided in the RAM 13. Then, the process proceeds to step S151 in FIG.

  In step S290, it is determined how many times the comparison has been performed until the difference between the first pressure value P1 and the y-th pressure value Py exceeds the gas leakage reference value ΔP. If it is less than the second comparison number reference value K, it is determined that the gas leakage is moderate, and the process proceeds to step S300 (Y in S290), and if it is equal to or greater than the second comparison number reference value K, the process proceeds to step S310 (N in S290). ).

  In step S300, assuming that the degree of gas leakage is medium, a value “2” indicating “gas leaking” is stored in the gas leakage degree information area provided in the RAM 13. Then, the process proceeds to step S151 in FIG.

  In step S310, assuming that the degree of gas leakage is small, a value “3” indicating “small gas leakage” is stored in the gas leakage degree information area provided in the RAM 13. Then, the process proceeds to step S151 in FIG.

  In step S 151, the gas leakage degree information stored in the gas leakage degree information area provided in the RAM 13 is read out and stored in the gas leakage degree information signal, and this gas leakage degree information signal is sent via the I / O unit 14. Transmit to the operation unit 2.

  Steps S120 and S130 described above correspond to the drive control means described in the claims, step S140 corresponds to the pressure value measuring means, and steps S150 and S151 correspond to the pressure information output means. Steps S210 to S250 also correspond to pressure value change measuring means, and steps S250, S270, and S290 also correspond to gas leakage degree determining means.

  Next, an example of the gas leakage degree measuring operation according to the present invention in the gas shutoff system 52 will be described.

  In the gas shut-off system 51, in order to measure the degree of gas leakage, when the operator depresses the operation button 21a while depressing the operation button 21c, the valve 4 is moved to the fully closed position accordingly, and the gas flow path 3 is completely closed. A closed state (blocking state) is entered, and the pressure value change in the downstream gas pipe 31b within a predetermined time is measured. Specifically, the pressure value of the downstream side gas pipe 31b is measured every 60 seconds, and the pressure value measured for the first time and the pressure value measured thereafter are sequentially compared. Then, when the difference exceeds a predetermined gas leak reference value ΔP, the number of comparisons taken until the difference exceeds the predetermined reference value is determined as a comparison number reference value n, Compared with J and K, the degree of gas leakage is determined (that is, the degree of gas leakage is determined from the time until the pressure drops by the gas leakage reference value ΔP within a predetermined time). Then, the determined degree of gas leak is displayed on the display unit 22 as “no leak”, “large gas leak”, “gas leaking”, and “small gas leak”.

  As described above, according to the present invention, the valve 4 is positioned at the pressure measurement position corresponding to the pressure information request signal (that is, the gas leak level request signal, the normal pressure request signal) input to the gas shut-off device 1, and then the downstream side. Since the pressure value in the side gas pipe 31b can be measured and information based on the pressure value can be output, there is no need to manually position the valve 4 at the pressure measurement position. Can be done.

  Moreover, since the change of the pressure value in the downstream gas pipe 31b within a predetermined time can be measured and the information indicating the degree of gas leakage according to the change can be output, the manual operation in the downstream gas pipe 31b can be performed. An operation for measuring a change in pressure value is not necessary, and therefore, an investigation operation associated with gas leakage can be performed more easily and accurately.

  Further, the gas shutoff device 1 and information corresponding to the pressure information signal output from the gas shutoff device 1 after transmitting the pressure information request signal to the gas shutoff device 1 (that is, the pressure value in the downstream gas pipe 31b) are displayed. Operation unit 2 that can perform easy operation and clear information display using the operation unit 2 without connecting a survey device such as a personal computer. And it can be done accurately. Further, for example, the gas shut-off device 1 and the operation unit 2 can be disposed at a distance such as the gas shut-off device 1 being disposed outdoors and the operation unit 2 being disposed indoors. Work by operation becomes possible, and investigation work accompanying gas leakage can be easily performed.

  In the first and second embodiments described above, the pressure sensor 6 is disposed closer to the gas pipe 31b on the downstream side than the valve 4. However, the pressure sensor 6 is not limited to this, and the pressure sensor 6 is disposed on the valve 4 side. It may be arranged closer to the upstream gas pipe 31a.

  In addition, embodiment mentioned above only showed the typical form of this invention, and this invention is not limited to embodiment. That is, various modifications can be made without departing from the scope of the present invention.

It is a gas interruption | blocking system which shows 1st (2nd) embodiment of this invention. It is a block diagram which shows the structure and connection of a microcomputer of a gas cutoff device. It is a flowchart which shows an example of the process which concerns on this invention of CPU with which a gas cutoff device is provided in 1st Embodiment. It is a flowchart which shows an example of the process which concerns on this invention of CPU with which a gas interruption | blocking apparatus is provided in 2nd Embodiment. It is a flowchart (continuation) which shows an example of the process which concerns on this invention of CPU with which a gas cutoff device is provided in 2nd Embodiment. It is a figure which shows the conventional gas cutoff valve.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Gas cutoff device 2 Operation unit 3 Gas flow path (flow path)
4 Valve (Valve)
5 Driving means 6 Pressure sensor 10 Microcomputer (MPU)
11 CPU
11a Drive control means (CPU)
11b Pressure value measuring means (CPU)
11c Pressure information output means (CPU)
11d Pressure value change measuring means (CPU)
11e Gas leak level determination means (CPU)
51, 52 Gas shut-off system

Claims (3)

In a gas shut-off device having a flow path connected to a gas pipe, a valve body that is incorporated in the flow path and opens and closes the flow path, and a drive unit that drives the valve body,
A pressure sensor for measuring a pressure value in the gas pipe;
Drive control means for positioning the valve body at a pressure measurement position arbitrarily determined for each pressure information request signal by the drive means in response to a pressure information request signal input from the outside;
Pressure value measuring means for measuring the pressure value by the pressure sensor after the valve body is positioned at the pressure measuring position by the drive control means;
Pressure information output means for outputting a pressure information signal based on the pressure value measured by the pressure value measuring means;
A gas shut-off device comprising: Pressure value change measuring means for measuring a change in the pressure value measured by the pressure value measuring means within a predetermined time; and
A gas leakage degree determination means for determining the degree of gas leakage based on the change in the pressure value measured by the pressure value change measurement means, and
2. The gas shut-off device according to claim 1, wherein the pressure information output means is a means for outputting a gas leakage degree information signal corresponding to the degree of gas leakage determined by the gas leakage degree determination means. A gas shut-off device according to claim 1 or 2, and an operation unit for inputting the pressure information request signal to the gas shut-off device, and
The operation unit displays information corresponding to the pressure information signal or the gas leakage degree information signal output from the pressure information output means of the gas shut-off device in response to the input pressure information request signal. A gas shut-off system characterized by that.

Images