JP2015224978A - Piping capacity estimation device, gas leakage inspection device, piping capacity estimation method, and piping capacity estimation program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a piping capacity estimation device, a gas leakage inspection device, a piping capacity estimation method, and a piping capacity estimation program with which it is possible to estimate a piping capacity in a downstream-side gas passageway with high accuracy, compared with the case where a configuration according to the present invention is not possessed.SOLUTION: A control device 20 derives a piping capacity in a downstream-side gas passageway 24B on the basis of the result of detection by a gas flowmeter 16 in a state in which a gas G is being consumed by a gas appliance 28 and the characteristic of a temporal change of gas pressure detected by a pressure sensor 18 when a gas passageway 24 is closed by a solenoid valve 14 in a state in which the gas G is being consumed by the gas appliance 28, and outputs the derived piping capacity.

Description

  The present invention relates to a pipe capacity estimation apparatus, a gas leak inspection apparatus, a pipe capacity estimation method, and a pipe capacity estimation program.

  In general, the capacity of the gas pipe can be easily measured by knowing the length of the measurement section and the cross-sectional area of the pipe. Conventionally, when judging gas leakage from gas supply piping, it is judged from fluctuations in gas pressure or changes in flow rate, etc. However, if pipe capacity is added as information to this, more accurate gas corresponding to the individual inner pipe capacity is used. It is possible to make a leak determination.

  In the conventional technology, since the pipe capacity cannot be calculated unless the length of the pipe and the diameter of the pipe are measured each time, it takes time and trouble to measure, and it is difficult to know the pipe capacity in a short time. Therefore, it is difficult to quickly and accurately determine the gas leak in the gas leak inspection.

  As an example of a technique for solving such a problem, for example, a technique described in Patent Document 1 is known.

  In Patent Document 1, the pipe capacity in the gas flow path downstream of the gas flow path blocking means is estimated from the time transition of the gas pressure detected by the gas pressure detection means when the gas flow path blocking means of the microcomputer meter is returned. Technology is disclosed.

Japanese Patent No. 3445677

  However, the technique described in Patent Document 1 is such that the displacement of the gas pressure when the gas flow path blocking means is restored (when the gas flow path is opened) is an instantaneous displacement. There was a problem that it was difficult to accurately estimate the capacity.

  The present invention has been made to solve the above-described problems, and a pipe capacity estimation device capable of accurately estimating the pipe capacity in the downstream gas flow path as compared with the case where the configuration according to the present invention is not provided. An object of the present invention is to provide a gas leakage inspection device, a pipe capacity estimation method, and a pipe capacity estimation program.

  The pipe capacity estimation device according to claim 1 is provided with an opening / closing means for opening / closing a gas flow path through which a gas flows, and a gas in a downstream gas flow path downstream from an installation position of the opening / closing means in the gas flow path. The gas is detected by gas flow rate detection means for detecting a flow rate, gas pressure detection means for detecting the gas pressure in the downstream gas flow path, and consumption means for consuming gas supplied through the downstream gas flow path. The detection result by the gas flow rate detection means in the consumed state, and the gas pressure detection means when the gas flow path is closed by the opening / closing means in the state where the gas is consumed by the consumption means. Output means for deriving and outputting the pipe capacity in the downstream gas flow path based on the detected temporal change characteristic of the gas pressure.

  The pipe capacity estimation device according to claim 2 controls the opening / closing means so that the gas flow path is closed when the gas flow rate converges to a constant value while the gas is consumed by the consumption means. And further includes control means.

  In the pipe capacity estimation device according to claim 3, the detection result is a representative gas flow rate detected by the gas flow rate detection unit in a state where the gas is consumed by the consumption unit.

  5. The pipe capacity estimation apparatus according to claim 4, wherein the representative gas flow rate is detected by the gas flow rate detection unit when the gas flow rate converges to a constant value while the gas is consumed by the consumption unit. Gas flow rate.

  In the pipe capacity estimating apparatus according to claim 5, the representative gas flow rate is an average value of gas flow rates detected within a predetermined time in a state where the gas is consumed by the consuming means.

  In the pipe capacity estimation device according to claim 6, the characteristic is a time transition of the gas pressure detected a plurality of times by the gas pressure detecting means.

  The pipe capacity estimation device according to claim 7 has correlation information in which a correlation between the detection result, the time transition, and the pipe capacity is predetermined, and the output unit detects the detection from the correlation information. The piping capacity corresponding to the result and the time transition is derived and output.

  In the pipe capacity estimation apparatus according to claim 8, the characteristic is a descent time required for a gas pressure detected by the gas pressure detecting means to drop per unit pressure.

  The pipe capacity estimation device according to claim 9 has correlation information in which a correlation between the detection result, the descent time, and the pipe capacity is predetermined, and the output means detects the detection from the correlation information. The piping capacity corresponding to the result and the descent time is derived and output.

  The gas leak inspection apparatus according to claim 10 is based on the pipe capacity estimation apparatus according to any one of claims 1 to 9 and the pipe capacity output by output means in the pipe capacity estimation apparatus. And inspection means for inspecting gas leakage.

  The pipe capacity estimation method according to claim 11 detects a gas flow rate in a downstream gas flow path downstream of an installation position of an opening / closing means for opening and closing the gas flow path among gas flow paths through which gas flows. Detecting the gas pressure in the downstream gas flow path, and detecting the gas flow rate in a state where the gas is consumed by the consuming means for consuming the gas supplied through the downstream gas flow path, And the pipe capacity in the downstream gas flow path based on the characteristics of the change over time of the gas pressure detected when the gas flow path is closed by the opening and closing means while the gas is consumed by the consumption means Is derived and output.

  A pipe capacity estimation program according to a twelfth aspect is a pipe capacity estimation program for causing a computer to function as output means in the pipe capacity estimation device according to any one of the first to ninth aspects.

  According to the first and tenth to twelfth aspects of the present invention, it is possible to accurately estimate the pipe capacity in the downstream gas flow path as compared with the case where the configuration according to the present invention is not provided.

  According to the second aspect of the present invention, compared to a case where the opening / closing means is not controlled so that the gas flow path is closed when the gas flow rate converges to a constant value while the gas is being consumed. The effort required to close the gas flow path can be reduced.

  According to the third aspect of the present invention, as a result of detection by the gas flow rate detection unit, the gas flow rate detection unit uses the representative gas flow rate detected by the gas flow rate detection unit while the gas is being consumed. The detection result can be easily obtained.

  According to the invention of claim 4, when the gas flow rate detected by the gas flow rate detection means is not used when the gas flow rate converges to a constant value while the gas is consumed, the representative gas flow rate is not used. In comparison, a highly reliable detection result can be used for derivation of the pipe capacity.

  According to the fifth aspect of the present invention, the representative gas flow rate is more reliable than the case where the average value of the gas flow rate detected within a predetermined time in a state where the gas is consumed is not used. A high detection result can be used for derivation of the pipe capacity.

  According to the invention which concerns on Claim 6, compared with the case where it does not have the structure where piping capacity is derived based on the detection result in the state where gas is consumed, and the time transition of the gas pressure detected several times, The pipe capacity can be estimated with high accuracy.

  According to the invention of claim 7, the pipe capacity is compared with the case where the detection result, the time transition, and the correlation of the pipe capacity do not have a configuration for deriving and outputting the pipe capacity without using the predetermined correlation information. Can be easily realized.

  According to the eighth aspect of the present invention, the time required for the gas pressure detected by the gas pressure detecting unit to drop per unit pressure is not used as the time-dependent change characteristic of the gas pressure detected by the gas pressure detecting unit. Compared to the case, the pipe capacity can be estimated quickly.

  According to the ninth aspect of the present invention, the pipe capacity is compared with a case in which the correlation between the detection result, the descent time, and the pipe capacity is not derived and output without using the predetermined correlation information. Can be easily realized.

  According to the tenth aspect of the present invention, the gas leak is detected with higher accuracy than the case where there is no configuration in which the gas leak is inspected based on the pipe capacity output by the output means in the pipe capacity estimating device according to the present invention. can do.

It is a schematic structure figure showing an example of the appearance composition of the gas management device concerning an embodiment. It is a block diagram which shows an example of the hardware constitutions of the electric system of the gas management apparatus which concerns on embodiment. It is a conceptual diagram which shows an example of the memory content of the secondary memory | storage part contained in the gas management apparatus which concerns on embodiment. It is a graph which shows an example of the composition of the pipe capacity presumption table memorized by the secondary storage part contained in the gas management device concerning an embodiment. It is a flowchart which shows an example of the piping capacity estimation process which concerns on embodiment. It is a conceptual diagram which shows an example of the correspondence of piping capacity | capacitance, pressure drop amount, and gas leak amount. It is a flowchart which shows an example of the gas leak test process which concerns on embodiment. It is a graph (graphed piping capacity estimation table) showing an example of a time transition of gas pressure when no gas leak occurs and an example of a time transition of gas pressure when gas leak occurs. It is a graph (graphed piping capacity estimation table) showing a modification of the configuration of the piping capacity estimation table stored in the secondary storage unit included in the gas management device according to the embodiment.

  Hereinafter, an example of an embodiment for carrying out the present invention will be described in detail with reference to the drawings.

  As an example, as shown in FIG. 1, a gas meter 10 (an example of a pipe capacity estimation apparatus and a gas leak inspection apparatus according to the present invention) according to the present embodiment includes a housing 12. The casing 12 includes a solenoid valve 14 as an example of an opening / closing means according to the present invention, a gas flow meter 16 as an example of a gas flow rate detection means according to the present invention, and a pressure as an example of a gas pressure detection means according to the present invention. A sensor 18 and a control device 20 are accommodated. Further, a part of the gas pipe 22 is accommodated in the housing 12. A gas flow path 24 through which a gas G supplied from a gas supply source (not shown) flows is formed in the gas pipe 22.

  In the gas pipe 22 accommodated in the housing 12, an electromagnetic valve 14, a gas flow meter 16, and a pressure sensor 18 are sequentially installed from the upstream side to the downstream side of the gas flow path 24. The gas flow path 24 is roughly divided into an upstream gas flow path 24A upstream of the installation position of the electromagnetic valve 14 and a downstream gas flow path 24B downstream of the installation position of the electromagnetic valve 14. .

  A pressure detection port 22A is formed on the downstream side of the installation position of the pressure sensor 18 in the gas pipe 22, and the pressure detection port 22A is covered with an openable / closable lid 26. For example, a gas adsorption device (not shown) is connected to the pressure detection port 22A. When the gas adsorption device is connected to the pressure detection port 22A, the gas G supplied from the upstream gas flow channel 24A to the downstream gas flow channel 24B is adsorbed by the gas adsorption device.

  A gas appliance 28 (an example of a consumption means according to the present invention) is connected to the end of the downstream gas flow path 24B. The gas appliance 28 is an appliance (for example, a gas stove) that consumes the gas G supplied via the downstream gas flow path 24B.

  The electromagnetic valve 14 opens and closes the gas flow path 24. The gas flow meter 16 detects the gas flow rate in the downstream gas flow path 24B. The pressure sensor 18 detects the gas pressure in the downstream gas flow path 24B.

  In this embodiment, the gas flow rate (liter / h) per unit time (for example, 1 hour) at a specific time point is adopted as an example of the gas flow rate. As an example of the flow rate, an average gas flow rate of several tens of seconds (for example, 30 seconds) may be used. The specific time point refers to, for example, a time point when the determination is affirmed in Step 102 of the pipe capacity estimation process described later. Hereinafter, for convenience of explanation, the gas flow rate per unit time at a specific time point is simply referred to as “gas flow rate”.

  As an example, as shown in FIG. 2, the control device 20 includes a CPU (Central Processing Unit) 30, a primary storage unit 32, a secondary storage unit 34, a timer 36, and an input / output interface (I / O) 40. Including. The CPU 30, the primary storage unit 32, the secondary storage unit 34, the timer 36, and the I / O 40 are connected to each other via a bus 38.

  The CPU 30 controls the overall operation of the gas meter 10. The primary storage unit 32 is a volatile memory, for example, a RAM (Random Access Memory). The secondary storage unit 34 is a non-volatile memory, for example, an EEPROM (Electrically Erasable and Programmable), a flash memory, or an HDD (Hard Disk Drive). The timer 36 measures time according to the instruction of the CPU 30. The time count by the timer 36 is reset by the CPU 30.

  The I / O 40 electrically connects the CPU 30 and various input / output devices, and controls transmission / reception of various information between the CPU 30 and various input / output devices. The gas meter 10 includes a gas flow meter 16 and a pressure sensor 18 as an input / output device that is electrically connected to the CPU 30 via the bus 38 by being connected to the I / O 40. Further, the gas meter 10 includes an external interface (I / F) 42 and a drive circuit 44 as input / output devices connected to the I / O 40.

  The communication I / F 42 controls transmission / reception of various types of information between the terminal device 46 and the CPU 30 owned by a meter reader, an installer, etc. (hereinafter referred to as “user”) of the gas meter 10. The communication I / F 42 is realized by, for example, an A / D converter (not shown), a transmission / reception circuit (not shown), an antenna (not shown), and the like. The communication I / F 42 establishes a communication path with the terminal device 46 by associating with the terminal device 46, thereby setting the terminal device 46 as a communication destination and communicating with the terminal device 46 according to an instruction from the CPU 30. Perform wireless communication.

  The terminal device 46 is provided with a reception unit (not shown) including a hard key, a switch, and the like, and the terminal device 46 performs wireless communication with the gas meter 10 according to an instruction received by the reception unit. Further, the terminal device 46 is provided with a display (not shown), and the terminal device 46 displays various information received from the gas meter 10 by performing wireless communication with the gas meter 10.

  The drive circuit 48 is connected to the electromagnetic valve 14 and drives the electromagnetic valve 14 in accordance with an instruction from the CPU 30.

  As an example, as shown in FIG. 3, the secondary storage unit 34 includes a pipe capacity estimation program 50 and a gas leak inspection program 52 (in the following, for convenience of explanation, if there is no need to distinguish between them, no reference numerals are given. (Referred to as “program”).

  The CPU 30 operates as an output unit according to the present invention by reading the pipe capacity estimation program 50 from the secondary storage unit 34, developing it in the primary storage unit 32, and executing the pipe capacity estimation program 50.

  That is, the CPU 30 determines the downstream side gas flow path based on the detection result of the gas flow meter 16 in a state where the gas is consumed by the gas appliance 28 and the characteristics of the gas pressure detected by the pressure sensor 18 over time. The pipe capacity at 24B is derived and output. Hereinafter, for convenience of explanation, the “pipe capacity in the downstream gas flow path 24B” is simply referred to as “pipe capacity”.

  Here, the characteristic of the gas pressure over time is the gas pressure detected by the pressure sensor 18 when the gas flow path 24 is closed by the electromagnetic valve 14 while the gas is being consumed by the gas appliance 28. The characteristic of change with time.

  Further, the CPU 30 reads out the pipe capacity estimation program 50 from the secondary storage unit 34, develops it in the primary storage unit 32, and executes the pipe capacity estimation program 50, thereby operating as a control unit according to the present invention.

  That is, the CPU 30 controls the electromagnetic valve 14 so that the gas flow path 24 is closed when the gas flow rate converges to a certain value while the gas G is consumed by the gas appliance 28.

  Here, whether or not the gas flow rate has converged to a constant value is determined by the gas flow meter 16 in which the gas flow rate of the same value is continuously several times (for example, 30 times) every unit time (for example, 1 second). Although it is performed by determining whether or not it has been detected, the present invention is not limited to this. For example, the determination as to whether or not the gas flow rate has converged to a constant value is made based on a predetermined time (for example, 30) as the time when the gas flow rate converges to a constant value from the start of the flow of the gas G to the downstream gas flow path 24B. It may be performed by determining whether or not (second) has elapsed.

  Further, the CPU 30 operates as an inspection unit according to the present invention by reading the gas leakage inspection program 52 from the secondary storage unit 34, developing it in the primary storage unit 32, and executing the gas leakage inspection program 52.

  That is, the CPU 30 checks for gas leakage based on the pipe capacity estimated (derived) by executing the pipe capacity estimation program 50.

  Here, a case where the program is read from the secondary storage unit 34 is illustrated, but it is not always necessary to store the program in the secondary storage unit 34 from the beginning. For example, the program may first be stored in a portable storage medium that is connected to the gas meter 10 and used. The CPU 30 may acquire the program from these portable storage media and execute the program. Moreover, you may memorize | store a program in the memory | storage part of external computers, such as a computer connected to the gas meter 10 via a communication means, or a server apparatus. In this case, the CPU 30 acquires a program from the external electronic computer and executes it.

  As an example, as shown in FIG. 3, the secondary storage unit 34 stores a pipe capacity estimation table 54. The pipe capacity estimation table 54 shows the detection result of the gas flow meter 16 when the gas G is consumed by the gas appliance 28, the time transition of the gas pressure detected a plurality of times by the pressure sensor 18, and the downstream gas flow. It is correlation information which shows the correlation of the pipe capacity in the path 24B.

  In the present embodiment, the correspondence relationship between the detection result by the gas flow meter 16 in a state where the gas G is consumed by the gas appliance 28 and the time transition of the gas pressure detected a plurality of times by the pressure sensor 18 is defined. A pipe capacity estimation table 54 is assigned for each pipe capacity.

  FIG. 4 shows an example of a pipe capacity estimation table 54 relating to a pipe capacity of 50 liters. In the example shown in FIG. 4, the time transition of the gas pressure detected a plurality of times per unit time by the pressure sensor 18 when the gas flow rate detected by the gas flow meter 16 is 50 liter / h and 200 liter / h, respectively. Is stipulated. For example, when the gas appliance 28 is a gas stove, “50 liter / h” indicates the gas flow rate when the gas stove is set to medium fire, and “200 liter / h” indicates the gas flow rate when the gas stove is set to high fire. Indicates.

  In addition, in the example shown in FIG. 4, although the time transition of the gas pressure regarding each of gas flow rate 50 liter / h and 200 liter / h is prescribed | regulated, this invention is not limited to this, Other than this The time transition of the gas pressure with respect to the gas flow rate may be further defined.

  Next, the pipe capacity estimation process performed by the CPU 30 when the CPU 30 executes the pipe capacity estimation program 50 when a predetermined condition (estimation start condition) is satisfied as a condition for starting the pipe capacity estimation process will be described with reference to FIG. Will be described with reference to FIG.

  Here, it is assumed that the execution of the pipe capacity estimation process is started in a state where the gas flow path 24 is filled with the gas G and the gas flow path 24 is closed by the electromagnetic valve 14. . Here, it is assumed that the execution of the pipe capacity estimation process is started in a state where the gas G is consumed by the gas appliance 28. For example, when the gas appliance 28 is a gas stove, the state where the gas G is consumed by the gas appliance 28 is a state in which the gas G is burned by setting the heating power adjustment switch of the gas stove to “medium flame”. Say. The estimation start condition is, for example, a condition that a reset switch (not shown) provided in the gas meter 10 is turned on, or an estimation start instruction is input to the gas meter 10 via the terminal device 46. These conditions are listed.

  In the piping capacity estimation process shown in FIG. 5, first, in step 100, the CPU 30 opens the gas flow path 24 by driving the electromagnetic valve 14, and then proceeds to step 102.

  In step 102, the CPU 30 determines whether or not a predetermined flow rate stabilization condition is satisfied as a condition for stabilizing the gas flow rate. In this step 100, as an example of the flow rate stabilization condition, a condition that the gas flow rate of the same value is continuously detected a plurality of times per unit time by the gas flow meter 16 is adopted. It is not limited to. For example, the time measurement by the timer 36 is started in response to the execution of the processing of step 100, and the condition that the time measured by the timer 36 has reached a preset time (for example, 30 seconds) is set as the flow rate. It may be adopted as a stable condition.

  If the flow rate stabilization condition is not satisfied in step 102, the determination is negative and the determination in step 102 is performed again. If the flow rate stabilization condition is satisfied in step 102, the determination is affirmed and the routine proceeds to step 104.

  In step 104, the CPU 30 causes the gas flow meter 16 to detect the gas flow rate, stores the detected gas flow rate (an example of the representative gas flow rate according to the present invention) in the primary storage unit 32, and then proceeds to step 106. Transition.

  In step 106, the CPU 30 closes the gas flow path 24 by driving the electromagnetic valve 14, and then proceeds to step 108.

  In step 108, the CPU 30 causes the pressure sensor 18 to detect the gas pressure, stores the detected gas pressure in the primary storage unit 32 in time series, and then proceeds to step 110. Note that when the processing of step 108 is executed, the timer 36 is reset, and the timer 36 starts counting time.

  In step 110, the CPU 30 determines whether or not a pressure detection end condition for ending the detection of the gas pressure by the pressure sensor 18 is satisfied. As an example of the pressure detection end condition, it is assumed that the gas pressure is detected a predetermined number of times (for example, 100 times) in step 108, or that the pressure detection end instruction is input to the gas meter 10 via the terminal device 46. These conditions are listed.

  If the pressure detection end condition is not satisfied in step 110, the determination is negative, and the routine proceeds to step 112. If the pressure detection end condition is satisfied in step 110, the determination is affirmed and the routine proceeds to step 114.

  In step 112, the CPU 30 refers to the time measured by the timer 36 and determines whether or not a first predetermined time has elapsed since the processing of step 108 was executed. In this step 112, 1 second is adopted as an example of the first predetermined time, but the present invention is not limited to this, and the gas pressure is detected a predetermined number of times until the pressure detection end condition is satisfied. Any time may be used as long as it is possible.

  In step 112, if the first predetermined time has not elapsed since the processing in step 108 was executed, the determination is negative and the determination in step 112 is performed again. In step 112, if the first predetermined time has elapsed after the processing of step 108 is executed, the determination is affirmed, and the routine proceeds to step 108.

  In step 114, the CPU 30 performs piping from the pipe capacity estimation table 54 according to the time transition of the gas flow rate stored in the primary storage unit 32 in step 104 and the gas pressure stored in the primary storage unit 32 in step 108. Deriving capacity.

  In this step 114, for example, the correspondence between the gas flow rate stored in the primary storage unit 32 in step 104 and the time transition of the gas pressure stored in the primary storage unit 32 in step 108 matches within a predetermined error. The pipe capacity estimation table 54 for which the relationship is defined is searched. Then, the pipe capacity is uniquely specified from the pipe capacity estimation table 54 obtained by the search. For example, the correspondence relationship between the gas flow rate stored in the primary storage unit 32 in step 104 and the time transition of the gas pressure stored in the primary storage unit 32 in step 108 matches the correspondence relationship shown in FIG. 4 within a predetermined error. When doing so, it is uniquely specified that the pipe capacity is 50 liters.

  In this step 114, 1% is adopted as an example of the predetermined error. However, the present invention is not limited to this, and a value less than 1% or a value exceeding 1% is set as the predetermined error. Needless to say, it may be adopted.

  In step 116, the CPU 30 outputs the pipe capacity information indicating the pipe capacity derived in step 114 to a predetermined output destination, and then ends the pipe capacity estimation process.

  Here, the predetermined output destination refers to, for example, the secondary storage unit 34 or the terminal device 46. When receiving the pipe capacity information, the terminal device 46 displays the pipe capacity indicated by the received pipe capacity information on the display.

  In the present embodiment, the case where the gas meter 10 is not provided with a display is illustrated, but when the gas meter 10 is provided with a display, the pipe capacity may be displayed on the display.

  As an example, as shown in FIG. 6, there is a constant between the pipe capacity estimated by executing the pipe capacity estimation process (the pipe capacity derived in step 114) and the pressure drop due to gas leakage. It is known that there is a corresponding relationship. That is, when the pipe capacity is classified as “large”, “medium”, and “small”, when the pipe capacity is “small” and when the pipe capacity is “large”, the pressure drop amount is small. The amount of gas leakage increases as the state increases. In the case of the same pressure drop amount, the amount of gas leakage increases as the pipe capacity increases.

  Therefore, the gas meter 10 detects the gas leak with higher accuracy than before by performing the gas leak inspection process shown in FIG. 7 as an example using the pipe capacity estimated by executing the pipe capacity estimation process. It becomes possible.

  Next, with respect to the gas leak inspection process performed by the CPU 30 when the CPU 30 executes the gas leak inspection program 52 when a predetermined condition (inspection start condition) is satisfied as a condition for starting the gas leak inspection process, FIG. Will be described with reference to FIG.

  Here, it is assumed that execution of the gas leakage inspection process is started in a state where the gas flow path 24 is closed by the electromagnetic valve 14. Here, it is assumed that the execution of the gas leakage inspection process is started in a state where the gas appliance 28 is not operating. The above-described inspection start condition is, for example, a condition that an inspection start switch (not shown) provided in the gas meter 10 is turned on, or an inspection start instruction is input to the gas meter 10 via the terminal device 46. The condition of the case is mentioned.

  In the gas leakage inspection process shown in FIG. 7, first, in step 150, the CPU 30 opens the gas flow path 24 by driving the electromagnetic valve 14, and then proceeds to step 152.

  In step 152, the CPU 30 closes the gas flow path 24 by driving the electromagnetic valve 14, and then proceeds to step 154. In step 152, for example, a predetermined time (for example, 5 seconds) elapses from when the processing of step 150 is completed until the gas G is fully filled in the downstream gas flow path 24B. In this case, the electromagnetic valve 14 is driven and the gas flow path 24 is closed.

  In step 154, the CPU 30 causes the pressure sensor 18 to detect the gas pressure, and then proceeds to step 156. When the process of step 154 is executed, the timer 36 starts counting time.

  In step 156, the CPU 30 determines whether or not the gas pressure detected by the pressure sensor 18 in step 154 has reached (decreased) a predetermined pressure. Here, the predetermined pressure means, for example, a gas pressure P1 lower than the gas pressure P0 when no gas leakage occurs, as shown in FIG. In addition, in the example shown in FIG. 8, graph A is an example of the time transition of the gas pressure when no gas leak occurs (normal time), and graph B shows the case where gas leak occurs (abnormal time). It is an example of the time transition of gas pressure.

  In step 156, if the gas pressure detected by the pressure sensor 18 in step 154 has not reached (decreased) the predetermined pressure, the determination is negative, and the routine proceeds to step 158. In step 156, if the gas pressure detected by the pressure sensor 18 in step 154 has reached (decreased) the predetermined pressure, the determination is affirmed and the routine proceeds to step 160.

  In step 158, the CPU 30 refers to the time measured by the timer 36 and determines whether or not a second predetermined time (time T1 in the example shown in FIG. 8) has elapsed since the processing of step 152 was executed. judge. Here, the second predetermined time is determined according to the pipe capacity estimated by executing the pipe capacity estimation process. The second predetermined time is derived by, for example, a table or an arithmetic expression. That is, a table or an arithmetic expression in which the correspondence between the pipe capacity and the second predetermined time is defined is stored in advance in the secondary storage unit 34, and the CPU 30 reads the table or the arithmetic expression from the secondary storage unit 34. Referred to.

  In step 158, if the second predetermined time has not elapsed since the processing of step 152 was executed, the determination is negative and the routine proceeds to step 154. In step 158, if the second predetermined time has elapsed since the processing of step 152 was executed, the determination is affirmed and the routine proceeds to step 162.

  In step 160, the CPU 30 executes the abnormal process, and thereafter ends the gas leak inspection process. The abnormal process is a process performed by the CPU 30 when a gas leak occurs. Examples of the abnormal process include a process for sounding a buzzer (not shown), a process for blinking a lamp (not shown), and a process for transmitting gas leak occurrence information indicating that a gas leak has occurred to the terminal device 46. At least one of the processes.

  In step 162, the CPU 30 executes a normal process, and then ends the gas leak inspection process. The normal process is a process performed by the CPU 30 when no gas leak occurs. As an example of the normal process, at least one of a process of opening the gas flow path 24 by driving the electromagnetic valve 14 and a process of notifying that no gas leakage has occurred is mentioned. Note that the process for notifying that no gas leak has occurred means, for example, a process for transmitting no gas leak information indicating that no gas leak has occurred to the terminal device 46 or that no gas leak has occurred. A process for outputting a voice message using a speaker (not shown).

  As described above, in the gas meter 10, the detection result by the gas flow meter 16 when the gas G is consumed, and when the gas flow path 24 is closed while the gas G is consumed are detected. The pipe capacity is derived based on the characteristics of the change in gas pressure over time. Therefore, the gas meter 10 does not have a configuration in which the pipe capacity is derived based on the detection result when the gas G is consumed and the characteristics of the gas pressure over time when the gas G is consumed. Compared to the case, the pipe capacity can be estimated with high accuracy.

  Further, in the gas meter 10, the electromagnetic valve 14 is controlled so that the gas flow path 24 is closed when the gas flow rate converges to a certain value while the gas G is consumed (step 106). Therefore, the gas meter 10 has a configuration in which the solenoid valve 14 is not controlled so that the gas flow path 24 is closed when the gas flow rate converges to a constant value while the gas G is consumed. Time and effort required for closing the flow path can be reduced.

  Further, in the gas meter 10, the representative gas flow rate detected by the gas flow meter 16 in a state where the gas G is consumed is adopted as a detection result by the gas flow meter 16. Therefore, the gas meter 10 detects the detection result by the gas flow meter 16 as compared with the case where the representative gas flow rate detected by the gas flow meter 16 is not used as the detection result by the gas flow meter 16. It can be obtained easily.

  In the gas meter 10, the representative gas flow rate is detected by the gas flow meter 16 when the gas flow rate converges to a constant value while the gas G is consumed (when the determination in step 102 is affirmative). Gas flow rate is adopted. Therefore, the gas meter 10 is more reliable than the case where the gas flow rate detected by the gas flow meter 16 is not used when the gas flow rate converges to a constant value while the gas G is consumed as the representative gas flow rate. A highly reliable detection result can be used to derive the pipe capacity.

  Further, in the gas meter 10, the pipe capacity is derived based on the detection result by the gas flow meter 16 in the state where the gas G is consumed and the time transition of the gas pressure detected a plurality of times by the pressure sensor 18 (step). 114). Therefore, the gas meter 10 has a pipe capacity that is smaller than that in a case where the pipe capacity is not derived based on the detection result in the state where the gas G is consumed and the time transition of the gas pressure detected a plurality of times. It can be estimated with high accuracy.

  Further, in the gas meter 10, the pipe capacity corresponding to the detection result by the gas flow meter 16 in a state where the gas G is consumed and the time transition of the gas pressure detected a plurality of times is derived from the pipe capacity estimation table 54. And output (steps 114 and 116). Therefore, the gas meter 10 can easily realize highly accurate estimation of the pipe capacity as compared with a case where the pipe capacity is not derived and output without using the pipe capacity estimation table 54.

  Further, in the gas meter 10, the gas leak is inspected by executing the gas leak inspection process based on the pipe capacity estimated by executing the pipe capacity estimation process. Therefore, the gas meter 10 has a gas leak compared to a case where the gas leak inspection process is executed based on the pipe capacity estimated by executing the pipe capacity estimation process and does not have a configuration in which the gas leak is inspected. Can be detected with high accuracy.

  In the above embodiment, the case where the pipe capacity is estimated based on the time transition of the gas pressure and the gas flow rate is illustrated, but the present invention is not limited to this. For example, the pipe capacity may be estimated based on the drop time (hereinafter referred to as “fall time”) required for the drop of the gas pressure per unit pressure detected by the pressure sensor 18 and the gas flow rate. In this case, since the CPU 30 can calculate the descent time by detecting the gas pressure at least twice, the CPU 30 can estimate the pipe capacity more quickly than when detecting the gas pressure three times or more. it can.

  Further, when estimating the pipe capacity based on the descent time and the gas flow rate, the CPU 30 estimates the pipe capacity by using a pipe capacity estimation table 60 shown in FIG. 9 as an example. In the example shown in FIG. 9, as an example of the descent time, the time required for the descent per 0.1 (kPa) is shown, and 10 seconds, 5 seconds, and 2 seconds are illustrated. In the pipe capacity estimation table 60, the correspondence between the pipe capacity and the gas flow rate is defined for each descent time. In this way, the pipe capacity is derived using the pipe capacity estimation table 60, so that it is easier to quickly estimate the pipe capacity than when the pipe capacity is derived without using the pipe capacity estimation table 60. Can be realized.

  In the example shown in FIG. 9, 10 seconds, 5 seconds, and 2 seconds are given as examples of the fall time, but the present invention is not limited to this, and each of the four or more fall times is provided. The correspondence relationship between the pipe capacity and the gas flow rate may be defined.

  In the above embodiment, the pipe capacity estimation table 54 is illustrated, but the present invention is not limited to this, and an arithmetic expression that functions in the same manner as the pipe capacity estimation table 54 may be used. Here, the arithmetic expression is, for example, an input value (gas flow rate and time transition) used when deriving the pipe capacity from the pipe capacity estimation table 54 is an independent variable, and is uniquely specified from the pipe capacity estimation table 54. This is an arithmetic expression using the pipe capacity as a dependent variable.

  Further, when the CPU 30 estimates the pipe capacity based on the descent time and the gas flow rate, the pipe capacity may be estimated using an arithmetic expression instead of the pipe capacity estimation table 60. As an example of the arithmetic expression used in this case, the input values (gas flow rate and descent time) used when deriving the pipe capacity from the pipe capacity estimation table 60 are set as independent variables, and are uniquely determined from the pipe capacity estimation table 60. An arithmetic expression using the specified pipe capacity as a dependent variable is given.

  In the above embodiment, the gas flow rate detected when the flow rate stabilization condition is satisfied is exemplified (step 104), but the present invention is not limited to this. For example, an average value of the gas flow rate detected within a predetermined time (for example, until the flow rate stabilization condition is satisfied) in a state where the gas G is consumed may be employed. As a result, the gas meter 10 provides a highly reliable detection result for derivation of the pipe capacity as compared with the case where the average value of the gas flow rate detected within a predetermined time is not used while the gas is being consumed. be able to. Further, here, the average value of the gas flow rate is illustrated as a variation of the representative gas flow rate detected within a predetermined time while the gas G is consumed, but the present invention is limited to this. is not. For example, as the representative gas flow rate detected within a predetermined time while the gas G is being consumed, the median value of the gas flow rates detected within a predetermined time while the gas G is being consumed , The mode value, or a value corresponding to these may be used.

  Moreover, in the said embodiment, although the case where the gas G was consumed by the gas appliance 28 was mentioned as an example as a precondition which execution of a piping capacity estimation process is started demonstrated, this invention is limited to this. is not. For example, the pipe capacity estimation process may be started on the precondition that the gas G is consumed by the gas adsorption device connected to the pressure detection port 22A. A combustor may be employed instead of the gas adsorption device.

  In the above-described embodiment, an example in which the CPU 30 refers to the time measured by the timer 36 has been described, but the present invention is not limited to this. For example, the CPU 30 may measure time by counting the number of clocks using a built-in timer function.

  Moreover, in the said embodiment, although the pipe capacity estimation program 50 and the gas leak test program 52 were illustrated, this is an example to the last. Therefore, it goes without saying that unnecessary steps may be deleted, new steps may be added, and the processing order may be changed within a range not departing from the spirit. In addition, each process included in each of the pipe capacity estimation process and the gas leak inspection process described in the above embodiment may be realized by a hardware configuration such as an ASIC (Application Specific Integrated Circuit) or a programmable logic device. Each process included in each of the pipe capacity estimation process and the gas leak inspection process described in the above embodiment may be realized by a combination of a hardware configuration and a software configuration.

DESCRIPTION OF SYMBOLS 10 Gas meter 14 Solenoid valve 16 Gas flow meter 18 Pressure sensor 24 Gas flow path 24B Downstream gas flow path 28 Gas appliance 30 CPU
50 Pipe capacity estimation program 52 Gas leak inspection program 54, 60 Pipe capacity estimation table

Claims (12)

Opening and closing means for opening and closing the gas flow path through which the gas flows;
A gas flow rate detecting means for detecting a gas flow rate in a downstream gas flow path downstream from an installation position of the opening / closing means in the gas flow path;
Gas pressure detecting means for detecting the gas pressure in the downstream gas flow path;
The detection result by the gas flow rate detection means when the gas is consumed by the consumption means for consuming the gas supplied through the downstream gas flow path, and the gas is consumed by the consumption means. When the gas flow path is closed by the opening / closing means in a state, the pipe capacity in the downstream gas flow path is derived and output based on the characteristics of the gas pressure detected by the gas pressure detection means over time. Output means for
Piping capacity estimation device.   The control unit according to claim 1, further comprising a control unit that controls the opening / closing unit so that the gas flow path is closed when the gas flow rate converges to a constant value while the gas is consumed by the consumption unit. Pipe capacity estimation device.   The pipe capacity estimation device according to claim 1, wherein the detection result is a representative gas flow rate detected by the gas flow rate detection unit in a state where the gas is consumed by the consumption unit.   The piping according to claim 3, wherein the representative gas flow rate is a gas flow rate detected by the gas flow rate detection unit when the gas flow rate converges to a constant value while the gas is consumed by the consumption unit. Capacity estimation device.   The pipe capacity estimation device according to claim 3, wherein the representative gas flow rate is an average value of gas flow rates detected within a predetermined time while the gas is consumed by the consumption means.   The pipe capacity estimation device according to any one of claims 1 to 5, wherein the characteristic is a time transition of a gas pressure detected a plurality of times by the gas pressure detecting means. The correlation between the detection result, the time transition, and the piping capacity has predetermined correlation information,
The pipe capacity estimating apparatus according to claim 6, wherein the output means derives and outputs the pipe capacity according to the detection result and the time transition from the correlation information.   The pipe capacity estimation device according to any one of claims 1 to 5, wherein the characteristic is a descent time required for the gas pressure detected by the gas pressure detecting means to drop per unit pressure. Correlation between the detection result, the descent time, and the pipe capacity has predetermined correlation information,
The pipe capacity estimation device according to claim 8, wherein the output means derives and outputs the pipe capacity according to the detection result and the descent time from the correlation information. The pipe capacity estimation device according to any one of claims 1 to 9,
Inspection means for inspecting gas leakage based on the pipe capacity output by the output means in the pipe capacity estimation device;
Gas leak inspection device including. Detecting the gas flow rate in the downstream gas passage downstream of the installation position of the opening / closing means for opening and closing the gas passage among the gas passages through which the gas flows,
Detecting the gas pressure in the downstream gas flow path;
In the state where the gas is consumed by the consumption means for consuming the gas supplied through the downstream gas flow path, and in the state where the gas is consumed by the consumption means A pipe capacity estimation method comprising: deriving and outputting a pipe capacity in the downstream gas flow path based on characteristics of a change in gas pressure with time detected when the gas flow path is closed by the opening / closing means. Computer
A pipe capacity estimation program for functioning as output means in the pipe capacity estimation device according to any one of claims 1 to 9.