JP5237774B2 - measuring device - Google Patents

Description

The present invention relates to a measuring apparatus .

Conventionally, ultrasonic and thermal gas meters are known. In such a gas meter, the gas flow rate is measured once every about 2 seconds (see, for example, Patent Document 1 and Patent Document 2).
JP 2008-202948 A JP 2001-324368 A

  However, since the gas meter measures the gas flow rate for 24 hours at an interval of once every 2 seconds, the power consumption is not small. In addition, when the measurement interval is not limited to once every 2 seconds and is measured at a shorter measurement interval such as once every 0.2 seconds, the power consumption is further increased. In particular, the gas meter must be driven by a battery for 10 years during the verification period, and it is important to reduce power consumption.

  Therefore, it is possible to reduce power consumption by methods such as reducing measurement accuracy, but there are timings where high measurement accuracy is required in gas meters, such as when using gas appliances, and it is easy to reduce measurement accuracy. I can't.

  This problem is not limited to a gas meter as long as it is a measurement device that measures the flow rate of gas, and is a common problem.

The present invention has been made in order to solve such a conventional problem, and an object of the present invention is to provide a measuring device capable of preventing a decrease in measurement accuracy when necessary while suppressing power consumption. It is to provide.

In order to obtain the integrated flow rate , the measuring device of the present invention uses a normal measurement mode for measuring the gas flow rate in the flow path at a measurement interval every first predetermined time, and the use of a gas appliance installed on the downstream side of the gas flow path. And at least one of a gas flow rate and a gas pressure at a measurement interval every second predetermined time, and a power consumption is a normal measurement mode. Is a measurement device that has a simple measurement mode that detects gas flow rate and has a measurement accuracy that is less than or equal to the power consumption in the normal measurement mode and that is less than the measurement accuracy in the normal measurement mode. a flow rate sensor which outputs a signal, and a microcomputer for determining the flow rate in response to an electrical signal from the flow sensor, a peripheral circuits of the microcomputer, integrated amount by integrating the electrical signal input from the simple measurement mode at a flow rate sensor When it reaches a predetermined amount, the trigger signal generating circuit for generating a first trigger signal for the transition from the simplified measurement mode to the high speed measurement mode, when the first trigger signal is generated by the trigger signal generating circuit, a simple And a drive circuit that shifts the mode from the measurement mode to the high-speed measurement mode . In the high-speed measurement mode, at least one of the waveform frequency and the amplitude is obtained from at least one waveform of the measured gas flow rate and gas pressure. Based on the calculation result indicating at least one of the value or the frequency and amplitude of the waveform, the characteristic according to the vibration of the adjustment spring of the governor, and the characteristic according to the vibration due to the compressibility of the nozzle holder It is characterized by determining whether it is the use of the gas appliance which has a governor, or the use of the gas appliance which does not have a governor .

According to this measuring apparatus, since the trigger signal generation circuit is a peripheral circuit of the microcomputer, there is no need for processing by the microcomputer to generate the first trigger signal, and power consumption related to processing processing of the microcomputer can be suppressed. . Further, when the integrated amount by integrating the electrical signal input from the simple measurement mode at a flow rate sensor has reached a predetermined amount, the first trigger signal for the trigger signal generating circuit is changed from the simple measurement mode to the high speed measurement mode Generate and shift to high-speed measurement mode . For this reason, for example, when the flow rate does not change, for example, zero, and the integrated amount does not reach the predetermined amount, that is, when there is no need for high-precision measurement, the measurement accuracy is measured in the normal measurement mode. The apparatus is driven in a simple measurement mode with less power consumption but less than accuracy. On the other hand, when the gas flows out and the flow rate changes and the integrated amount reaches a predetermined amount, that is, when the need for relatively accurate measurement increases, the power consumption is reduced in the simple measurement mode. The apparatus is driven in the normal measurement mode with high measurement accuracy even though it is more than electric power. Therefore, it is possible to prevent a decrease in measurement accuracy when necessary while suppressing power consumption. Moreover, it has the normal measurement mode which measures a gas flow rate at the measurement interval for every 1st predetermined time, and the high-speed measurement mode which detects at least one of a gas flow rate and a gas pressure at the measurement interval for every 2nd predetermined time. For this reason, when the gas flows out in the simple measurement mode and the flow rate changes, and the integrated flow rate exceeds a predetermined value, the integrated flow rate can be obtained, or the use of the gas appliance and the gas leakage determination can be performed. . Further, in the high-speed measurement mode, a value obtained by obtaining at least one of the waveform frequency and amplitude from at least one waveform of the measured gas flow rate and gas pressure, or at least one state of the waveform frequency and amplitude is indicated. Based on the calculation result, it is determined whether the gas appliance having the governor or the gas appliance having no governor is used. Here, there is a characteristic difference in the frequency and amplitude of the pressure and flow waveforms between the start of use of the gas appliance having the governor and the start of use of the gas appliance having no governor. Therefore, it is judged whether it is the use of the gas appliance with the governor or the use of the gas appliance without the governor among the gas appliances by this characteristic difference, and it leads to prevention of false detection of the gas leak judgment. be able to.

In the measurement apparatus of the present invention, the microcomputer inputs the first trigger signal from the trigger signal generation circuit, transmits an instruction signal for shifting the mode from the simple measurement mode to the high-speed measurement mode , and drives the drive circuit. The circuit preferably inputs an instruction signal from the microcomputer and shifts the mode from the simple measurement mode to the high-speed measurement mode .

According to this measuring apparatus, the microcomputer inputs the first trigger signal from the trigger signal generation circuit and transmits an instruction signal, and the drive circuit inputs the instruction signal from the microcomputer and performs high-speed measurement from the simple measurement mode. Change mode to mode. For this reason, compared with the case where the first trigger signal is directly input to the drive circuit, the circuit connection from the trigger signal generation circuit to the drive circuit becomes unnecessary, and the configuration can be simplified.

In the measurement apparatus of the present invention, it is preferable that the drive circuit inputs the first trigger signal from the trigger signal generation circuit and shifts the mode from the simple measurement mode to the high-speed measurement mode .

According to this measuring apparatus, the drive circuit inputs the first trigger signal from the trigger signal generation circuit and shifts the mode from the simple measurement mode to the high-speed measurement mode . That is, the first trigger signal from the trigger signal generation circuit is directly input to the drive circuit without going through the microcomputer, and the microcomputer is not involved in the mode transition from the simple measurement mode to the high-speed measurement mode . Power consumption can be reduced.

  The measuring apparatus according to the present invention further includes switch means for inputting a first trigger signal from the trigger signal generating circuit to be turned on, and the microcomputer outputs the first trigger signal from the trigger signal generating circuit to switch means. It is preferable that the power supply voltage is supplied by turning on.

  According to this measuring apparatus, the microcomputer is supplied with the power supply voltage by outputting the first trigger signal from the trigger signal generating circuit and turning on the switch means. For this reason, the microcomputer is turned on when the mode is changed from the second mode to the first mode, and is in a stopped state until the mode is changed. Therefore, power consumption can be further reduced.

Further, the measuring apparatus of the present invention, the trigger signal generating circuit, when the accumulated amount by integrating the electrical signal input from the simple measurement mode at a flow rate sensor has reached a predetermined amount, the transition from the simplified measurement mode to the high speed measurement mode The microcomputer generates a first trigger signal for performing the normal operation from the high-speed measurement mode after at least one of the gas flow rate and the gas pressure is detected at a measurement interval every second predetermined time for a specific time in the high-speed measurement mode. A second trigger signal to be shifted to the measurement mode is generated, and when the first trigger signal is generated from the trigger signal generation circuit, the drive circuit shifts the mode from the simple measurement mode to the high-speed measurement mode, and the microcomputer triggers the second trigger. When a signal is generated, it is preferable to shift the mode from the high-speed measurement mode to the normal measurement mode.

According to this measuring apparatus, when the integrated amount by integrating the electrical signal input from the simple measurement mode at a flow rate sensor has reached a predetermined amount, and proceeds from the simple measurement mode fast measurement mode, the specific time in the high speed measurement mode Therefore, after at least one of the gas flow rate and the gas pressure is detected at the measurement interval every second predetermined time, the high-speed measurement mode is shifted to the normal measurement mode. For this reason, when the gas flows out and the flow rate changes in the simple measurement mode , and the integrated flow rate exceeds a predetermined value, first, the high-speed measurement mode is shifted to, and then the normal measurement mode is shifted. Thus, when the gas flow is detected, the use state of the gas appliance and the gas leakage are instantaneously determined in the high-speed measurement mode, and thereafter, the normal measurement for obtaining the integrated flow rate is performed. Thereby, it can transfer to normal measurement after safety checks, such as a gas leak.

In the measurement apparatus of the present invention, when the microcomputer determines that a flow rate exceeding a predetermined value is not detected based on the electrical signal from the flow sensor in the normal measurement mode, the microcomputer shifts from the normal measurement mode to the simple measurement mode . The trigger signal is generated, and the drive circuit preferably shifts from the normal measurement mode to the simple measurement mode when the third trigger signal is generated from the microcomputer.

According to this measuring apparatus, when the flow rate exceeding the predetermined value is not detected in the normal measurement mode, the normal measurement mode is shifted to the simple measurement mode . As described above, when the flow rate does not exceed a predetermined value (for example, 1.5 L / hr) and there is no gas flow, that is, when there is no need to integrate the flow rate and use of gas appliances or gas leakage. Therefore, the simple measurement mode is entered, and the power consumption can be reduced appropriately.

In the measurement apparatus of the present invention, when the flow sensor is a thermal type, it is preferable that the heater voltage in the simple measurement mode is smaller than the heater voltage in the normal measurement mode.

According to this measuring apparatus, when the flow rate sensor is a thermal type, the heater voltage in the simple measurement mode is made smaller than the heater voltage in the normal measurement mode. For this reason, when the gas flow rate is detected by a thermal method, the power consumption used for the heater can be reduced.

  In the measurement apparatus of the present invention, it is preferable that the measurement interval in the high-speed measurement mode is shorter than the measurement interval in the normal measurement mode.

  According to this measuring apparatus, the measurement interval in the high-speed measurement mode is shorter than the measurement interval in the normal measurement mode. For this reason, when measuring the use state of gas appliances and gas leakage, detailed measurement is performed to increase the determination accuracy, and when an integrated flow rate is desired, measurement such as once every two seconds may be performed. it can.

  In the measurement apparatus of the present invention, when the flow sensor is a thermal type, the heater voltage in the high-speed measurement mode is preferably smaller than the heater voltage in the normal measurement mode.

  According to this measuring apparatus, when the flow rate sensor is a thermal type, the heater voltage in the high-speed measurement mode is made smaller than the heater voltage in the normal measurement mode. For this reason, in the high-speed measurement mode and normal measurement mode which have the measurement accuracy more than 2nd mode, it can be set as a different sensitivity, and the convenience can be improved.

  In the measurement apparatus of the present invention, it is preferable that the trigger signal generation circuit includes an integration circuit.

  According to this measuring apparatus, since the trigger signal generating circuit is configured to include the integrating circuit, the high frequency component of the electrical signal from the flow sensor is cut by the integrating circuit, and the first trigger signal is generated by the high frequency component. The frequency of erroneous output can be suppressed.

According to the present invention, it is possible to provide a measuring apparatus capable of preventing a reduction in measurement accuracy when necessary while suppressing power consumption.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the drawings. FIG. 1 is a configuration diagram of a gas supply system including a measuring device according to the first embodiment of the present invention. The gas supply system 1 supplies fuel gas to each gas appliance 10, and includes a plurality of gas appliances 10, a gas supply source regulator 20, pipes 31 and 32, a gas meter (measuring device) 40, and the like. It has. In the example illustrated in FIG. 1, the gas meter 40 is described as an example of a measuring device, but the measuring device is not limited to the gas meter 40 and may be other devices that measure the gas flow rate.

  The adjuster 20 adjusts the fuel gas from the upstream to a predetermined pressure and flows it through the first pipe 31. The first pipe 31 connects the regulator 20 and the gas meter 40. The second pipe 32 is a pipe that connects the gas meter 40 and the gas appliance 10. The gas meter 40 measures the flow rate of the fuel gas and displays the integrated flow rate. In such a gas supply system 1, a flow path connected to the first pipe 31 and the second pipe 32 is formed in the gas meter 40, and the fuel gas flowing through the regulator 20 flows from the first pipe 31 to the gas meter 40, And the gas appliance 10 is reached through the second pipe 32 and burned in the gas appliance 10.

  The gas appliance 10 generally includes a shut-off valve 12, a governor 13, and a burner 14. The shut-off valve 12 is a valve provided in the gas appliance 10. The governor 13 has a governor inner valve 13a, and adjusts the pressure of the gas supplied to the burner 14 of the gas appliance 10 by the opening degree of the governor inner valve 13a. The pressure-adjusted fuel gas reaches the burner 14 through the nozzle 13b at the tip of the governor 13 and burns. Note that not all the gas appliances 10 have the governor 13, and some gas appliances 10 do not have the governor 13 such as a gas stove.

  FIG. 2 is a side sectional view showing an example of the governor 13 shown in FIG. In addition, in FIG. 2, only an example of the governor 13 is shown, and the configuration of the governor 13 is not limited to that shown in FIG. Further, the governor 13 shown in FIG. 2 is illustrated with the nozzle 13b shown in FIG. 1 omitted.

  As shown in FIG. 2, the governor 13 uses a part of the internal space formed by the outer wall 13c and the governor cap 13d as a gas flow path. Such a governor 13 includes a diaphragm 13e, an adjustment spring 13f, and an adjustment screw 13g in the internal space in addition to the governor inner valve 13a.

  The diaphragm 13 e is a film-like member that partitions the internal space of the governor 13. A governor inner valve 13a is attached to the diaphragm 13e on one side (flow channel side). Further, an adjustment spring 13f is attached to the other side (side not functioning as a flow path) of the diaphragm 13e. The adjustment spring 13f has a diaphragm 13e attached to one end and an adjustment screw 13g attached to the other end. The adjustment screw 13g is structured to be fixed to the inner wall of the governor 13 in which the thread groove is formed, and the compression rate of the adjustment spring 13f can be changed by changing the fixing position with the thread groove. Further, the adjusting screw 13g is not exposed to the outside, and has a structure covered with a governor cap 13d.

  The outer wall 13c of the governor 13 is formed with an air hole 13h that communicates with the other side of the diaphragm 13e. For this reason, the other side of the diaphragm 13e is air pressure. Further, in the example shown in FIG. 2, the governor inner valve 13a has a hemispherical shape, and the opening ratio of the passage port 13i can be controlled by vertical movement.

  In such a governor 13, when the gas pressure on the gas inlet side increases, the diaphragm 13e is pushed up, and at the same time, the governor inner valve 13a attached to the diaphragm 13e is also raised. Thereby, the opening ratio of the passage port 13i becomes small, and the gas flow rate decreases. On the other hand, when the gas pressure on the gas inlet side is lowered, the diaphragm 13e is lowered, and at the same time, the governor inner valve 13a attached to the diaphragm 13e is also lowered. Thereby, the opening ratio of the passage port 13i increases, and the gas flow rate increases. In this manner, the governor 13 adjusts the downstream pressure by keeping the downstream flow rate constant with respect to the upstream pressure fluctuation.

  FIG. 3 is a configuration diagram of the gas meter 40 according to the first embodiment of the present invention. The gas meter 40 shown in the figure includes a flow sensor 41, a pressure sensor 42, a microcomputer 47, a trigger signal generation circuit 48, and a drive circuit 49.

  The flow sensor 41 is installed in the flow path in the gas meter 40 and outputs an electrical signal corresponding to the gas flow rate in the flow path. The flow sensor 41 preferably outputs an analog voltage that monotonously increases or monotonously decreases according to the flow rate. Moreover, the flow sensor 41 may be comprised from the sensor part which outputs 1 pulse for every predetermined flow, and the circuit which inputs a pulse and performs frequency / voltage conversion. In the following description, the flow sensor 41 will be described by taking as an example a thermal sensor such as a flow sensor configured by a heater that generates a temperature distribution and a thermopile that generates a signal corresponding to the temperature distribution.

  The pressure sensor 42 is for detecting the gas pressure of the gas present in the flow path in the gas meter 40. The pressure sensor 42 is not limited to the flow path in the gas meter 40, and may be installed in the first pipe 31 or the second pipe 32 existing outside the gas meter 40 if possible. Similarly, the installation location of the flow sensor 41 can be changed.

  In this embodiment, the signals from the flow sensor 41 and the pressure sensor 42 are directly input to the microcomputer 47 in FIG. 3, but other elements such as an amplifier may be added between the two depending on circumstances. .

  The microcomputer 47 controls the entire gas meter 40 and performs flow rate integration control, display control, cutoff valve cutoff control, and the like. In the present embodiment, the microcomputer 47 includes a flow rate detection unit 47a and a trigger signal generation unit 47b. The flow rate detection unit 47 a obtains the flow rate according to the electrical signal from the flow rate sensor 41 input to the microcomputer 47. The trigger signal generator 47b generates an instruction signal for changing the measurement mode of the gas meter 40 and second and third trigger signals. In the present embodiment, the measurement mode of the gas meter 40 includes three modes: a simple measurement mode (second mode), a regular measurement mode (first mode), and a high-speed measurement mode (first mode).

  The trigger signal generation circuit 48 is a peripheral circuit of the microcomputer 47 and generates a first trigger signal. Specifically, the trigger signal generation circuit 48 outputs a first trigger signal when the electrical signal input from the flow sensor 41 is integrated and the integrated amount reaches a predetermined amount, and includes an integrating circuit 48a, And a pulse generation circuit 48b.

  The integrating circuit 48a includes a resistor R1, a capacitor C, an operational amplifier OP1, and a PNP transistor Q. Specifically, the integration circuit 48a inputs the electric signal from the flow sensor 41 to the operational amplifier OP1 via the resistor R1. The output of the operational amplifier OP1 is connected to one end of the capacitor C and the pulse generation circuit 48b. The other end of the capacitor C is connected to the input side of the operational amplifier OP1 and is connected to the emitter of the PNP transistor Q.

  The pulse generation circuit 48b includes an operational amplifier OP2 and resistors R2 and R3. The output side of the operational amplifier OP1 of the integrating circuit 48a is connected to the input side of the operational amplifier OP2, and is also connected to the resistors R2 and R3. The output of the operational amplifier OP2 is connected to the base of the PNP transistor Q. The collector of the PNP transistor Q is connected to a connection point A connecting resistors R2 and R3 connected to the input side of the operational amplifier OP2. Further, the output of the operational amplifier OP2 is connected to the input port P1 of the microcomputer 47. The signal output from the operational amplifier OP2 becomes the first trigger signal.

  The drive circuit 49 controls the drive of the flow sensor 41 and the pressure sensor 42, and includes a simple measurement mode drive circuit 49a, a high-speed measurement mode drive circuit 49b, and a regular measurement mode drive circuit 49c. These drive circuits 49a to 49c correspond to the three measurement modes described above. Accordingly, the simple measurement mode drive circuit 49a functions when the gas meter 40 is driven in the simple measurement mode, and the high-speed measurement mode drive circuit 49b functions when the gas meter 40 is driven in the high-speed measurement mode. Further, when it is desired to drive the gas meter 40 in the normal measurement mode, the normal measurement mode drive circuit 49c functions.

  Here, each measurement mode will be described. First, the regular measurement mode is a mode for detecting the gas flow rate in the flow path. Specifically, the flow rate sensor 41 is driven at a measurement interval once every first predetermined time, and every first predetermined time. This is a mode in which the flow rate detector 47a measures the gas flow rate at a single timing. The high-speed measurement mode is a mode in which the gas pressure in the flow path is detected. Specifically, the microcomputer 47 detects the gas pressure output from the pressure sensor 42 at a timing once every second predetermined time. It is. The simple measurement mode is continuous with low power consumption (“continuous” when the flow sensor 41 is a thermal sensor, but “high speed” when the flow sensor 41 is an ultrasonic sensor). In this mode, the flow rate sensor 41 is driven and an electric signal from the flow rate sensor 41 is input to the trigger signal generation circuit 48, whereby the gas flow rate is simply measured without the microcomputer 47.

  Each measurement mode will be described in more detail. The gas meter 40 is in the simple measurement mode mainly when the gas appliance 10 is not used. The simple measurement mode is a mode in which the power consumption is less than or equal to the power consumption in the regular measurement mode and the high-speed measurement mode, and the measurement accuracy is less than or equal to the measurement accuracy in the regular measurement mode and the high-speed measurement mode. Specifically, the simple measurement mode does not require extremely high measurement accuracy, and a certain amount of flow is generated from a state where the flow rate in the flow path is 1.5 L / hr or less (a state in which gas is not used). It is a mode that only needs to detect this.

  The regular measurement mode is a mode in which the gas flow rate is measured at a measurement interval of about once every 2 seconds in order to obtain the integrated flow rate. The gas meter 40 enters a normal measurement mode mainly when the gas appliance 10 is used, and increases the value of the integrated flow rate displayed on the meter body according to the gas flow rate. As described above, the regular measurement mode is a mode for obtaining the gas usage amount called the integrated flow rate, and therefore, the measurement accuracy higher than the simple measurement mode is required.

  The high-speed measurement mode is preferably a mode in which a pressure waveform showing a frequency of 300 Hz at maximum can be measured. The gas meter 40 is in a high-speed measurement mode until a specific time (about 0.3 second to about 2.0 seconds) elapses after a certain amount of gas starts flowing. In this high-speed measurement mode, the gas meter 40 captures a change in gas pressure, determines the use of the gas appliance 10 installed on the downstream side of the gas flow path, and determines whether a gas leak has occurred. . Note that there is a correlation between a change in gas pressure and a change in gas flow rate. Therefore, in the high-speed measurement mode, the gas flow rate may be measured at a measurement interval of about once every 1 millisecond, or both the gas pressure and the gas flow rate are measured at a measurement interval of about once every 1 millisecond. May be.

  Here, continuous measurement is performed in the simple measurement mode. In contrast, the measurement interval in the normal measurement mode is 2 seconds. For this reason, the measurement time is longer in the simple measurement mode, and if the same measurement is performed in the simple measurement mode and the normal measurement mode, the power consumption in the simple measurement mode becomes higher than in the normal measurement mode. Therefore, the gas meter 40 according to the present embodiment reduces the power consumption in the simple measurement mode by, for example, the following method.

  First, in a thermal gas meter such as a flow sensor, a gas flow rate is detected based on a temperature distribution generated by a heater. Therefore, when the supply voltage to the heater in the normal measurement mode is “1”, the supply voltage to the heater is about “1/4” in the simple measurement mode. As a result, the power consumption becomes “1/16”. The power consumption is not limited to “1/16”, but may be about “1/10”.

  When the gas flow rate is measured in the high-speed measurement mode, the supply voltage to the heater may be set to “1” as in the normal measurement mode, or the supply voltage to the heater is set to about “1/4” as in the simple measurement mode. It is good also as. Further, in the high-speed measurement mode, the supply voltage to the heater may be an intermediate value such as “1/2”.

  Further, in the present embodiment, the power consumption of the microcomputer 47 is reduced in the simple measurement mode. As will be described later with reference to FIG. 4, in the simple measurement mode, the microcomputer 47 does not require the flow rate or pressure measurement process until the first trigger signal is input to the input port P1, and the power consumption of the microcomputer 47 itself is reduced. ing. That is, in the simple measurement mode, when the trigger signal generation circuit 48 inputs the electrical signal from the flow sensor 41 and the trigger signal generation circuit 48 integrates the electrical signal and the integrated amount reaches a predetermined amount, the first trigger A simple flow rate detection of outputting a signal is performed, an accurate flow rate value is not calculated, and the power consumption itself of the microcomputer 47 is reduced. Therefore, as described above, in addition to changing the supply voltage of the heater, by suppressing the power consumption of the microcomputer 47, the overall power consumption in the gas meter 40 is suppressed. As a result, the power consumption in the simple measurement mode is The power consumption is less than the high-speed measurement mode or the regular measurement mode. In the simple measurement mode, an accurate flow rate is not measured, and the measurement accuracy in the simple measurement mode is less than the measurement accuracy in the high-speed measurement mode or the normal measurement mode.

  In the gas supply system 1 as described above, the mode of the gas meter 40 is changed as follows. FIG. 4 is a state transition diagram showing an outline of the mode transition method of the gas meter 40 according to the first embodiment. As shown in FIG. 4, first, when no gas is used, the gas meter 40 is in a simple measurement mode. At this time, the gas meter 40 continuously drives the flow sensor 41 with low power consumption, and the trigger signal generation circuit 48 inputs an electric signal that is continuously output.

  Further, the integrating circuit 48a of the trigger signal generating circuit 48 integrates the input electric signal. The pulse generation circuit 48b does not output the first trigger signal when the integrated amount does not reach the predetermined amount, and maintains the simple measurement mode. Thus, in the simple measurement mode, the microcomputer 47 does not perform the flow rate calculation and the power consumption of the microcomputer 47 is reduced.

  On the other hand, when the integrated amount reaches a predetermined amount in the simple measurement mode, that is, when a certain amount of flow occurs and the integrated amount reaches the predetermined amount (S1), the trigger signal generation circuit 48 outputs the first trigger signal. generate. Thereby, the trigger signal generator 47b of the microcomputer 47 generates an instruction signal for shifting from the simple measurement mode to the high-speed measurement mode. Then, the drive circuit 49 inputs an instruction signal to cause the high-speed measurement mode drive circuit 49b to function. Thereby, the gas meter 40 shifts to the high-speed measurement mode. At the same time, the microcomputer 47 outputs a switching signal for switching the selector switch 41 a that controls the output destination of the flow sensor 41. As a result, the electrical signal from the flow sensor 41 is input to the microcomputer 47.

  In addition, when the gas meter 40 shifts to the high-speed measurement mode, the gas meter 40 measures the gas pressure at a measurement interval of about once every millisecond, uses the gas appliance 10 with a governor, uses the gas appliance 10 without a governor, and leaks gas. It is judged whether it corresponds to any of the states.

  Further, the gas meter 40 performs pressure measurement for a specific time (for example, about 0.3 seconds to 1 second) in the high-speed measurement mode. And after specific time progress, the trigger signal generation part 47b produces | generates the 2nd trigger signal for making it transfer to high speed measurement mode from regular measurement mode. Thereby, the drive circuit 49 inputs the second trigger signal, causes the normal measurement mode drive circuit 49c to function, and shifts the gas meter 40 to the normal measurement mode (S2).

  When it is determined that gas leakage has occurred in the high-speed measurement mode, the gas meter 40 operates the shut-off valve to close the flow path and prevent gas leakage. In the high-speed measurement mode, in a special case, the high-speed measurement mode is continued even after a specific time has elapsed (S3). Here, the special case is, for example, a case where the gas appliance 10 has failed to ignite once and is expected to start the ignition operation again immediately after the failure.

  When shifting to the normal measurement mode, the normal measurement mode drive circuit 49c drives the flow sensor 41 once every about 2 seconds, and the flow rate detection unit 47a detects the gas flow rate at a measurement interval of about once every 2 seconds. Go.

  Then, it is assumed that a flow rate exceeding a predetermined value (for example, 1.5 L / hr) is not detected in the normal measurement mode. That is, it is assumed that the flow rate detected in the normal measurement mode is 1.5 L / hr or less in a state where it is determined that the gas is not used (S4). In this case, the trigger signal generator 47b generates a third trigger signal for shifting from the normal measurement mode to the simple measurement mode. And the drive circuit 49 inputs the 3rd trigger signal, makes the simple measurement mode drive circuit 49a function, and makes the gas meter 40 transfer to simple measurement mode. At the same time, the microcomputer 47 outputs a switching signal for switching the selector switch 41 a that controls the output destination of the flow sensor 41. As a result, the electrical signal from the flow sensor 41 is input to the trigger signal generation circuit 48. When shifting from the normal measurement mode to the simple measurement mode, the mode shift may be performed immediately after the use of the gas appliance 10 is finished and after it is determined that there is no gas leakage.

  In addition, when a signal is acquired only from the pressure sensor 42 in the high-speed measurement mode, the flow rate measurement is not performed, and the flow rate measurement is not performed during a specific time. Therefore, it is desirable to execute parallel processing that performs flow rate measurement equivalent to the normal measurement mode during the high-speed measurement mode. This is because the integrated flow rate can be obtained without losing the flow rate generated during the specific time.

  Next, the use of the gas appliance 10 in the high-speed measurement mode and a determination method for gas leakage will be described. When the gas appliance 10 with the governor is used, when the gas appliance 10 without the governor is used, and when a gas leak occurs, different pressure changes are shown. Specifically, when the pressure change is on the vertical axis and the time is on the horizontal axis, the amplitude and frequency of the pressure change are characteristic. In the high-speed measurement mode, the microcomputer 47 determines whether or not the governor-equipped gas appliance 10 is used, whether or not the governor-less gas appliance 10 is used, and whether a gas leak has occurred, from the amplitude and frequency of the pressure change. Determine whether.

  FIG. 5 is a graph showing how the pressure changes when the use of the gas appliance 10 with the governor is started. In FIG. 5, the vertical axis represents the pressure change amount (kPa), and the horizontal axis represents the elapsed time (seconds) after the use of the governor-equipped gas appliance 10 is started.

  When the use of the gas appliance 10 with the governor is started, the pressure becomes a stable state after exhibiting the predetermined amplitude shown in FIG. Specifically, immediately after the start of use of the gas appliance 10 with the governor, after showing a pressure drop to just “−0.1” kPa (see symbol a1), the pressure rises to about “0.05” kPa. (See symbol a2). After that, the pressure shows a pressure drop to about “−0.05” kPa (see symbol a3), and then shows a pressure rise to about “0.05” kPa (see symbol a4). Thereafter, the pressure repeatedly oscillates while the amplitude gradually decreases, and finally becomes a stable state in which there is no pressure change.

  The reason why such pressure vibration occurs is that an adjustment spring 13 f is provided in the governor 13. That is, when the use of the gas appliance 10 with the governor is started, the adjustment spring 13f vibrates, the governor inner valve 13a also vibrates, and the opening ratio of the passage port 13i changes gradually and gradually. Because it does.

  In particular, at the start of use of the gas appliance 10 with a governor, characteristics are seen in the frequency and amplitude of pressure vibration. Specifically, since the adjustment spring 13f vibrates in small increments, the pressure shows fine vibration. As a result, the pressure waveform contains many relatively high frequency components. Moreover, since the passage opening 13i becomes larger or smaller due to the vibration of the adjustment spring 13f at the start of use of the gas appliance 10 with a governor, the pressure waveform shows a large amplitude.

なる演算式で表すことができる。ここで、Ｃは振幅を示し、ｋは摩擦力（減衰定数）を示し、ωは復元力を示し、αは初期位置を示している。この式は多くの周波数ｆ_ｉ＝ω_ｉ／２πの振動の重ね合わせであることを示している。 The pressure P is

It can be expressed by the following equation. Here, C indicates the amplitude, k indicates the frictional force (attenuation constant), ω indicates the restoring force, and α indicates the initial position. This equation indicates that this is a superposition of vibrations of many frequencies f _i = ω _i / 2π.

  FIG. 6 is a graph showing the pressure change when the use of the governorless gas appliance 10 is started. In FIG. 6, the vertical axis represents the pressure change amount (kPa), and the horizontal axis represents the elapsed time (seconds) after the use of the governorless gas appliance 10 is started.

  When the use of the governorless gas appliance 10 is started, the pressure is in a stable state after showing the predetermined amplitude shown in FIG. Specifically, immediately after the start of use of the gas appliance 10 with the governor, after showing a pressure drop to “−0.1” kPa (see b1), the pressure rises to about “0.01” kPa. (See symbol b2). Thereafter, the pressure shows a pressure drop to about “−0.05” kPa (see symbol b3). Thereafter, the pressure repeatedly vibrates with no pressure increase. Then, the amplitude gradually decreases, and finally a stable state in which there is no pressure change is obtained. The reason why such pressure vibration occurs is as follows.

  FIG. 7 is a schematic view showing a state of supply of fuel gas in the governorless gas appliance 10. As shown in FIG. 7, when the governorless gas appliance 10 is used, the fuel gas reaches the burner 14 and the like from the second pipe 32 through the nozzle holder 100. Here, when a gas having a flow velocity flows into the nozzle holder 100, the flow rate does not decrease suddenly due to the inertial force, but the gas is compressed and the pressure rises. Thereafter, the inflow flow velocity becomes small (in some cases, a reverse flow) due to the increased pressure, and the pressure decreases. By repeating this, vibration of compression and expansion occurs.

  As described above, the pressure oscillates when the gas appliance with governor 10 is used and when the gas appliance 10 without governor is used. However, when the pressure waveform shown in FIG. 6 is compared with the pressure waveform shown in FIG. 5, there are the following differences.

  First, the governor-equipped gas appliance 10 has a substance that vibrates finely like the adjustment spring 13f, whereas the governor-less gas appliance 10 does not have such a substance. Therefore, although the pressure waveform shown in FIG. 6 shows vibration in the same manner as the pressure waveform shown in FIG. 5, the vibration frequency as a whole is lower than the pressure waveform shown in FIG.

Further, in the case of the gas appliance 10 with the governor, the amplitude is increased by the vibration of the adjustment spring 13f. However, in the case of the gas appliance 10 without the governor, there is no adjustment spring 13f, and vibration due to the compressibility of the nozzle holder 100 occurs. There is only. For this reason, the pressure waveform shown in FIG. 6 has a smaller amplitude than the pressure waveform shown in FIG.

  From such characteristics, the microcomputer 47 can determine whether the gas appliance with governor 10 is used or whether the gas appliance 10 without governor is used.

  FIG. 8 is a graph showing a state of pressure change at the time of gas leakage. In FIG. 8, the vertical axis represents the pressure change amount (kPa), and the horizontal axis represents the elapsed time (seconds) after the gas leak occurred.

  As shown in FIG. 8, when a gas leak occurs, the pressure gradually decreases without showing a clear vibration. Thus, in the case of gas leakage, neither the vibration of the adjustment spring 13f nor the vibration due to the compressibility of the nozzle holder 100 occurs, so no clear vibration is seen in the pressure waveform.

  As described above, there is a characteristic difference in the pressure waveform between the start of use of the gas appliance 10 with governor, the start of use of the gas appliance 10 without governor, and the occurrence of gas leakage. From the above characteristics, the microcomputer 47 can determine whether the gas appliance 10 with the governor is used, the gas appliance 10 without the governor, or the gas leak. In determining whether or not the gas appliance 10 with the governor is used, the microcomputer 47 may use a value of frequency or amplitude, or a calculation result indicating the frequency or amplitude (for example, spectral data obtained by Fourier transform). ) May be used.

  Next, the operation of the gas meter 40 according to the present embodiment will be described with reference to a flowchart. FIG. 9 is a flowchart showing details of the operation of the gas meter 40 according to the first embodiment, and shows the operation in the simple measurement mode.

  In the simple measurement mode, the flow rate sensor 41 is continuously driven by the simple measurement mode drive circuit 49a. For this reason, the trigger signal generation circuit 48 continuously inputs an electric signal. In such a state, the microcomputer 47 determines whether or not the first trigger signal is input (S10). Specifically, in the present embodiment, the first trigger signal is output at an integrated flow rate of 1 mL. For this reason, when there is a gas flow rate of 36 L / hr (= 10 mL / sec), the first trigger signal is output in 0.1 seconds (including errors, 0.1 seconds ± 0.01 seconds). . In addition, when using the gas appliance 10, it is unlikely that the flow rate is less than 40 L / hr, and the first trigger signal is output within 0.1 seconds when the gas appliance 10 is used. It will be.

  When it is determined that the first trigger signal has not been input (S10: NO), this process is repeated until it is determined that the first trigger signal has been input. On the other hand, if it is determined that the first trigger signal is input (S10: YES), the microcomputer 47 outputs a switching signal (S11). As a result, the output destination of the electrical signal from the flow sensor 41 is switched from the trigger signal generation circuit 48 to the microcomputer 47. Then, the trigger signal generator 47b of the microcomputer 47 outputs an instruction signal to the drive circuit 49 (S12). Thereby, the high-speed measurement mode drive circuit 49b of the drive circuit 49 functions, and the measurement mode shifts from the simple measurement mode to the high-speed measurement mode (S13). Thereafter, the process shown in FIG. 9 ends.

  FIG. 10 is a flowchart showing details of the operation of the gas meter 40 according to the first embodiment, and shows the operation in the high-speed measurement mode. As shown in FIG. 10, in the high-speed measurement mode, the microcomputer 47 determines whether or not a second predetermined time (specifically, 1 millisecond) has elapsed (S20). When it is determined that the second predetermined time has not elapsed (S20: NO), this process is repeated until it is determined that the second predetermined time has elapsed. If it is determined that the second predetermined time has elapsed (S20: YES), the microcomputer 47 resets the time measured (S21). And the microcomputer 47 memorize | stores the detected gas pressure while detecting the gas pressure in a flow path based on the signal from the pressure sensor 42 (S22).

  Thereafter, the microcomputer 47 determines whether or not a specific time (specifically, 0.3 seconds to 2.0 seconds) has elapsed (S23). In this process, the microcomputer 47 determines whether or not a specific time has elapsed depending on whether or not a predetermined number (eg, 300 to 1000) of pressure data has accumulated. If it is determined that the specific time has not elapsed (S23: NO), the process proceeds to step S20.

  On the other hand, if it is determined that the specific time has elapsed (S23: YES), the microcomputer 47 determines use of the gas appliance 10 or gas leakage based on the gas pressure data measured and stored in step S22 during the specific time. (S24). Thereafter, the microcomputer 47 determines whether or not there is no gas leakage in the process of step S24 (S25).

  If it is determined that there is no gas leak (S25: YES), the trigger signal generator 47b generates a second trigger signal (S26). Thereby, the normal measurement mode drive circuit 49c of the drive circuit 49 functions, and the measurement mode shifts from the high-speed measurement mode to the normal measurement mode (S27). Thereafter, the process shown in FIG. 10 ends.

  On the other hand, if it is not determined that there is no gas leak (S25: NO), that is, if it is determined that there is a gas leak, the microcomputer 47 shuts off the shutoff valve and issues an alarm (S28). Thereafter, the process shown in FIG. 10 ends.

  FIG. 11 is a flowchart showing details of the operation of the gas meter 40 according to the first embodiment, and shows the operation in the normal measurement mode. As shown in FIG. 11, in the normal measurement mode, the microcomputer 47 determines whether or not a first predetermined time (specifically, 2 seconds) has elapsed (S40). When it is determined that the first predetermined time has not elapsed (S40: NO), this process is repeated until it is determined that the first predetermined time has elapsed. On the other hand, if it is determined that the first predetermined time has elapsed (S40: YES), the microcomputer 47 resets the time measured (S41).

  Then, the flow rate detector 47a detects the gas flow rate in the flow path based on the signal from the flow rate sensor 41 (S42). Next, the microcomputer 47 determines whether or not the flow rate detected in step S42 is a flow rate exceeding a predetermined value (for example, 1.5 L / hr) (S43). If it is determined that the flow rate exceeds the predetermined value (S43: YES), the microcomputer 47 integrates the flow rate measured in step S42 (S44). Thereafter, the process proceeds to step S40.

  On the other hand, when it is determined that the flow rate does not exceed the predetermined value (S43: NO), the trigger signal generator 47b generates a third trigger signal (S45). Thereby, the simple measurement mode drive circuit 49a of the drive circuit 49 functions, and the measurement mode shifts from the normal measurement mode to the simple measurement mode (S46). Then, the microcomputer 47 outputs a switching signal (S47), and sets the output destination of the electrical signal from the flow sensor 41 as the trigger signal generation circuit 48. Thereafter, the process shown in FIG. 11 ends. In the process of step S43, if “NO” is determined only once, the process proceeds to the process of step S45. However, the present invention is not limited to this, and if “NO” is continuously determined a plurality of times in step S43. In addition, it is desirable to proceed to the process of step S45. This is because it is possible to prevent a transition to the simple measurement mode when the flow rate does not instantaneously exceed a predetermined value due to pulsation.

  FIG. 12 is a flowchart showing details of step S24 shown in FIG. 10, and shows processing related to use of the gas appliance 10 and determination of gas leakage. As shown in FIG. 12, first, the microcomputer 47 analyzes the frequency of the waveform of the gas pressure stored in step S22 of FIG. 10 (S60) and analyzes the amplitude (S61).

  Thereafter, the microcomputer 47 determines whether or not a frequency component equal to or higher than the discriminant value is included in the waveform based on the analysis result of step S60 (S62). If it is determined that a frequency component equal to or greater than the discriminant value is included (S62: YES), that is, if the frequency component includes many high frequency components such as the pressure waveform shown in FIG. 10 is used (S63). Then, the process illustrated in FIG. 12 ends, and the process proceeds to step S25 in FIG.

  If it is determined that the frequency component equal to or higher than the discriminant value is not included in the waveform (S62: NO), the microcomputer 47 first determines the amplitude value of the first peak (that is, the first amplitude after the pressure changes). The maximum value when the value increases in the positive direction, or the value when the amplitude becomes the maximum in the positive direction throughout the whole) is a predetermined amount as the original pressure (the pressure of “0” on the vertical axis in FIG. 5). It is determined whether or not it is equal to or greater than the added value (S64). When it is determined that the amplitude value of the first peak is equal to or larger than the value obtained by adding a predetermined amount to the original pressure (S64: YES), the microcomputer 47 determines that the gas appliance 10 with the governor is used (S63). Then, the process illustrated in FIG. 12 ends, and the process proceeds to step S25 in FIG.

  On the other hand, if it is determined that the amplitude value of the first mountain is not equal to or greater than the value obtained by adding a predetermined amount to the original pressure (S64: NO), the microcomputer 47 determines that the amplitude value of the first mountain is substantially equal to the original pressure. It is determined whether or not (specifically, the original pressure ± the specified value) (S65). If it is determined that the amplitude value of the first peak is substantially equal to the original pressure (S65: YES), the microcomputer 47 determines that the governorless gas appliance 10 is used (S66). Then, the process illustrated in FIG. 12 ends, and the process proceeds to step S25 in FIG.

  If it is determined that the amplitude value of the first peak is not substantially equal to the original pressure (S65: NO), the microcomputer 47 determines that the amplitude value of the first peak is equal to or less than a value obtained by subtracting a predetermined amount from the original pressure. It is determined whether or not (S67). When it is determined that the amplitude value of the first peak is equal to or less than the value obtained by subtracting the predetermined amount from the original pressure (S67: YES), the microcomputer 47 detects a flow rate that is equal to or greater than the specified amount based on the signal from the flow rate sensor 41. It is determined whether or not to be performed (S68).

  When it is determined that a flow rate equal to or greater than the specified amount is detected (S68: YES), that is, the characteristics of frequency and amplitude due to the use of the gas appliance 10 cannot be obtained, the gas pressure in the flow path decreases, and the specified amount If the above flow rate is detected, the microcomputer 47 determines that there is a gas leak (S69). Then, the process illustrated in FIG. 12 ends, and the process proceeds to step S25 in FIG.

  By the way, when it is determined that the amplitude value of the first peak is not less than or equal to the value obtained by subtracting the predetermined amount from the original pressure (S67: NO), and when it is determined that the flow rate exceeding the specified amount is not detected (S68: NO). The microcomputer 47 determines that neither the use of the gas appliance 10 nor the gas leakage falls (S70). Then, the process illustrated in FIG. 12 ends, and the process proceeds to step S25 in FIG.

  Note that the use of the gas appliance 10 and gas leakage are not limited to those shown in FIG. 12, and may be determined by other methods, for example. For example, if the microcomputer 47 determines “YES” in step S62 or step S64, the microcomputer 47 determines that the gas appliance with governor 10 is used, but not limited to this, “YES” in both step S62 and step S64. If it is determined, it may be determined that the gas appliance with governor 10 is used.

  Further, the microcomputer 47 may determine that the governor-equipped gas appliance 10 is used when the attenuation coefficient of the pressure waveform is equal to or less than a predetermined value. Further, the microcomputer 47 determines that the amplitude value of the first peak is the amplitude value of the first valley (that is, the minimum value when the amplitude first increases in the negative direction after the pressure changes, When the amplitude is smaller than the value when the amplitude is increased in the negative direction, it may be determined that the gas appliance 10 with the governor is used. Furthermore, you may judge use of the gas appliance 10 with a governor combining various above-mentioned content.

  Thus, according to the gas meter 40 according to the first embodiment, since the trigger signal generation circuit 48 is a peripheral circuit of the microcomputer 47, there is no need for processing by the microcomputer 47 to generate the first trigger signal. The power consumption related to the processing calculation of the microcomputer 47 can be suppressed. The first trigger for the trigger signal generation circuit 48 to shift from the second mode to the first mode when the electrical signals input from the flow sensor 41 in the second mode are integrated and the integrated amount reaches a predetermined amount. A signal is generated and the mode is shifted to the first mode. For this reason, for example, when the flow rate does not change at zero and the integrated amount does not reach a predetermined amount, that is, when there is no need for highly accurate measurement, the measurement accuracy is measured in the first mode. The apparatus is driven in the second mode with less power but less power consumption. On the other hand, when the gas flows out and the flow rate changes and the integrated amount reaches a predetermined amount, that is, when the necessity of relatively accurate measurement increases, the power consumption is consumed in the second mode. The apparatus is driven in the first mode in which the measurement accuracy is higher than the electric power but the measurement accuracy is high. Therefore, it is possible to prevent a decrease in measurement accuracy when necessary while suppressing power consumption.

  Further, the microcomputer 47 inputs the first trigger signal from the trigger signal generation circuit 48 and transmits an instruction signal, and the drive circuit 49 inputs the instruction signal from the microcomputer 47 and changes from the second mode to the first mode. Change mode to. For this reason, compared with the case where the first trigger signal is directly input to the drive circuit 49, the circuit connection from the trigger signal generation circuit 48 to the drive circuit 49 becomes unnecessary, and the configuration can be simplified.

  The first mode includes a normal measurement mode that measures the gas flow rate at a measurement interval every first predetermined time, and a high-speed measurement mode that detects at least one of the gas flow rate and the gas pressure at a measurement interval every second predetermined time. Consists of. For this reason, in the second mode, when the gas flows out and the flow rate changes and the integrated flow rate exceeds a predetermined value, the integrated flow rate may be obtained, or the use judgment of the gas appliance 10 or the gas leakage judgment may be performed. it can.

  Also, when the electrical signals input from the flow sensor 41 in the second mode are integrated and the integrated amount reaches a predetermined amount, the second mode is shifted to the high-speed measurement mode, and the second time is set for the specific time in the high-speed measurement mode. After at least one of the gas flow rate and the gas pressure is detected at a measurement interval every predetermined time, the high-speed measurement mode is shifted to the normal measurement mode. For this reason, when the gas flows out in the second mode and the flow rate changes, and the integrated flow rate exceeds a predetermined value, first, the high-speed measurement mode is shifted to, and then the normal measurement mode is shifted. Thereby, when the gas flow is detected, the use state of the gas appliance 10 and gas leakage are instantaneously determined in the high-speed measurement mode, and thereafter, the normal measurement for obtaining the integrated flow rate is performed. Thereby, it can transfer to normal measurement after safety checks, such as a gas leak.

  In the high-speed measurement mode, a value obtained by obtaining at least one of the waveform frequency and amplitude from at least one waveform of the measured gas flow rate and gas pressure, or at least one state of the waveform frequency and amplitude is indicated. Based on the calculation result, it is determined whether the gas appliance 10 having the governor 13 or the gas appliance 10 not having the governor 13 is used. Here, there is a characteristic difference in the frequency and amplitude of the waveform of pressure and flow rate between the start of use of the gas appliance 10 having the governor 13 and the start of use of the gas appliance 10 not having the governor 13. Therefore, it is determined by this characteristic difference whether the gas appliance 10 having the governor 13 or the gas appliance 10 not having the governor 13 is used. It can lead to prevention of false detection.

  Further, when the flow rate exceeding the predetermined value is not detected in the normal measurement mode, the normal measurement mode is shifted to the second mode. In this way, when the flow rate does not exceed a predetermined value (for example, 1.5 L / hr) and there is no gas flow, that is, there is no need to integrate the flow rate and use the gas appliance 10 or determine gas leakage. In this case, the mode is shifted to the second mode, and the power consumption can be appropriately reduced.

  In the simple measurement mode, the flow rate change is continuously monitored. For this reason, in the second mode, the measurement accuracy is equal to or less than the measurement accuracy in the normal measurement mode, but it is detected earlier that the flow has occurred from the state where the gas is not flowing, compared to the regular measurement mode in which the measurement is intermittently driven. Can do.

  When the flow sensor 41 is a thermal type, the heater voltage in the second mode is smaller than the heater voltage in the normal measurement mode. For this reason, when the gas flow rate is detected by a thermal method, the power consumption used for the heater can be reduced.

  In addition, the measurement interval in the high-speed measurement mode is shorter than the measurement interval in the regular measurement mode. For this reason, when determining the use state of the gas appliance 10 or gas leakage, it is possible to increase the determination accuracy by performing fine measurement.

  Moreover, when acquiring a signal only from the pressure sensor 42 in the high-speed measurement mode, it is desirable to execute parallel processing for performing flow rate measurement corresponding to the normal measurement mode during the high-speed measurement mode. As a result, the integrated flow rate can be obtained without losing the flow rate generated during the specific time.

  Further, since the trigger signal generation circuit 48 includes the integration circuit 48a, the high frequency component of the electrical signal from the flow sensor 41 is cut by the integration circuit 48a, and the first trigger signal is erroneously detected by the high frequency component. Can be suppressed. Specifically, when the trigger signal generation circuit 48 is configured to output the first trigger signal by integration of 1 mL, even if there is a flow rate vibration of 50 Hz, it is about 140 mL / sec (that is, 500 L / hr) or more. If there is no instantaneous flow rate, the first trigger signal is not output. As described above, the trigger signal generation circuit 48 according to the present embodiment is difficult to erroneously output the first trigger signal due to the high frequency noise.

  Next, a second embodiment of the present invention will be described. The gas meter 40 according to the second embodiment is substantially the same as that of the first embodiment, but a part of the configuration and processing are different. Only differences from the first embodiment will be described below.

  FIG. 13 is a configuration diagram of a gas meter 40 according to the second embodiment of the present invention. In FIG. 13, the internal configuration of the trigger signal generation circuit 48 is the same as that shown in FIG. As shown in FIG. 13, the gas meter 40 according to the second embodiment differs from the first embodiment in the output destination of the first trigger signal from the trigger signal generation circuit 48, and a new analog switch (switch means) 50 is provided. I have.

  In such a gas meter 40, the analog switch 50 is turned off in the simple measurement mode, and the microcomputer 47 is not supplied with the power supply voltage until the first trigger signal is input from the trigger signal generation circuit 48. ing.

  On the other hand, when the first trigger signal is output from the trigger signal generation circuit 48, the analog switch 50 is turned on. Further, the microcomputer 47 is supplied with the power supply voltage when the first trigger signal is output from the trigger signal generation circuit 48 and the analog switch 50 is turned on, and the microcomputer 47 is turned on.

  The first trigger signal is directly output to the changeover switch 41a and the drive circuit 49. As a result, the changeover switch 41a switches the output destination of the electrical signal to the microcomputer 47 side without depending on the switching signal from the microcomputer 47. Similarly, the drive circuit 49 causes the high-speed measurement mode drive circuit 49b to function without inputting an instruction signal from the microcomputer 47, and shifts from the simple measurement mode to the high-speed measurement mode.

  It should be noted that the changeover switch 41a, the drive circuit 49, and the analog switch 50 that have once input the first trigger signal need to be devised so as not to return from the mode transition state or the microcomputer on state to the state before the transition. Specifically, a logic circuit may be provided in the analog switch 50 so that the state before the transition is not restored unless there is a reset signal from a microcomputer (not shown). Alternatively, the hysteresis of the trigger signal generation circuit 48 may be increased so that the output from the trigger signal generation circuit 48 does not return to the OFF state if there is no reset signal from a microcomputer (not shown).

  By configuring the gas meter 40 as described above, the microcomputer itself can be stopped in the simple measurement mode, and the power consumption can be further suppressed.

  By the way, when the gas meter 40 according to the second embodiment shifts from the normal measurement mode to the simple measurement mode, a signal for turning off the analog switch 50 is output from the output port P2 to turn off the analog switch 50. Further, when shifting from the normal measurement mode to the simple measurement mode, a switching signal is output and the output destination is returned to the trigger signal generation circuit 48.

  Thus, according to the gas meter 40 which concerns on 2nd Embodiment, the effect similar to 1st Embodiment can be acquired.

  Further, according to the second embodiment, the drive circuit 49 receives the first trigger signal from the trigger signal generation circuit 48 and shifts the mode from the second mode to the first mode. That is, the first trigger signal from the trigger signal generation circuit 48 is directly input to the drive circuit 49 without going through the microcomputer 47, and the microcomputer is involved in the mode transition from the second mode to the first mode. In addition, power consumption can be further reduced.

  The microcomputer 47 is supplied with the power supply voltage when the trigger signal generating circuit 48 outputs the first trigger signal and the analog switch 50 is turned on. For this reason, the microcomputer 47 is turned on when the mode is shifted from the second mode to the first mode, and is in a stopped state until the mode is shifted. Therefore, power consumption can be further reduced.

  Note that recent microcomputers have functions such as low power consumption mode and sleep mode, and the mode can be switched by inputting a signal to the mode switching terminal. Therefore, the first trigger signal is input to such a terminal. Alternatively, the low power consumption mode may be switched to the normal mode.

  As described above, the present invention has been described based on the embodiment, but the present invention is not limited to the above embodiment, and may be modified without departing from the gist of the present invention. For example, in the present embodiment, the high-speed measurement mode is a measurement interval once per millisecond, but is not limited thereto, and may be a shorter measurement interval or a longer measurement interval, or the constant pressure sensor 42. May be driven to constantly detect the pressure, that is, the measurement interval may be 0.1 milliseconds.

  In the present embodiment, the trigger signal generation circuit 48 exists as a part of the gas meter 40. However, the present invention is not limited to this, and the trigger signal generation circuit 48 may be extracted from the gas meter 40 and configured as a trigger signal generation device. . Further, not only the trigger signal generation circuit 48 but also the trigger signal generation unit 47b and the drive circuit 49 may be taken out from the gas meter 40.

  Further, when the flow sensor 41 according to the present embodiment is a thermal sensor, it is desirable that the heater voltage in the high-speed measurement mode is smaller than the heater voltage in the normal measurement mode. Thereby, even in the high-speed measurement mode and the normal measurement mode having measurement accuracy higher than the simple measurement mode, different sensitivities can be obtained, and convenience can be improved.

  In the present embodiment, the flow sensor 41 has been described by taking a thermal sensor as an example. However, the present invention is not limited to this, and other sensors may be used. The flow sensor 41 is not limited to a sensor that outputs an analog voltage, and may output a current or a pulse voltage.

  In the present embodiment, the high-speed measurement mode and the normal measurement mode are exemplified as the second mode. However, the second mode is not limited to the high-speed measurement mode and the normal measurement mode, and may be only one of them. Three or more modes including these modes may be used.

  Furthermore, in the present embodiment, the high-speed measurement mode is only shifted to the normal measurement mode. However, the present invention is not limited to this, and the flow rate detected by the flow rate detector 47a in the high-speed measurement mode does not exceed a predetermined value. In this case, the high-speed measurement mode may be shifted to the simple measurement mode.

  In the present embodiment, the second trigger signal is output from the microcomputer 47. However, the present invention is not limited to this, and an analog circuit for generating the second trigger signal may be provided outside the microcomputer 47.

It is a lineblock diagram of a gas supply system containing a measuring device concerning a 1st embodiment of the present invention. FIG. 2 is a side sectional view showing an example of the governor shown in FIG. 1. It is a lineblock diagram of the gas meter concerning a 1st embodiment of the present invention. It is a state transition diagram showing the outline of the mode change method of the gas meter concerning a 1st embodiment. It is a graph which shows the mode of a pressure change when the use of the gas appliance with a governor is started. It is a graph which shows the mode of a pressure change when the use of a gas appliance without a governor is started. It is the schematic which shows the mode of supply of the fuel gas in a gas appliance without a governor. It is a graph which shows the mode of the pressure change at the time of gas leak. It is a flowchart which shows the detail of operation | movement of the gas meter which concerns on 1st Embodiment, and has shown operation | movement in simple measurement mode. It is a flowchart which shows the detail of operation | movement of the gas meter which concerns on 1st Embodiment, and has shown operation | movement in high-speed measurement mode. It is a flowchart which shows the detail of operation | movement of the gas meter which concerns on 1st Embodiment, and has shown operation | movement in regular measurement mode. It is a flowchart which shows the detail of step S24 shown in FIG. 10, and has shown the process regarding use of a gas appliance and a gas leak determination. It is a block diagram of the gas meter which concerns on 2nd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Gas supply system 10 ... Gas appliance 12 ... Shut-off valve 13 ... Governor 13a ... Governor inner valve 13b ... Nozzle 13c ... Outer wall 13d ... Governor cap 13e ... Diaphragm 13f ... Adjustment spring 13g ... Adjustment screw 13h ... Air hole 14 ... Burner 20 ... Adjuster 31 ... First pipe 32 ... Second pipe 40 ... Gas meter (measuring device)
41 ... Flow rate sensor 42 ... Pressure sensor 47 ... Microcomputer 47a ... Flow rate detection unit 47b ... Trigger signal generation unit 48 ... Trigger signal generation circuit 48a ... Integration circuit 48b ... Pulse generation circuit 49 ... Drive circuit 49a ... Simple measurement mode drive circuit 49b ... High-speed measurement mode drive circuit 49c ... Regular measurement mode drive circuit 50 ... Analog switch (switch means)

Claims (10)

In order to obtain the integrated flow rate, a normal measurement mode in which the gas flow rate in the flow path is measured at a measurement interval every first predetermined time, and the use of a gas appliance installed on the downstream side of the gas flow path are determined, and gas leakage In order to determine whether or not the gas has occurred, a high-speed measurement mode that detects at least one of a gas flow rate and a gas pressure at a measurement interval every second predetermined time, and power consumption is less than or equal to the power consumption in the regular measurement mode A measurement apparatus having a simple measurement mode for detecting a gas flow rate and having a measurement accuracy equal to or less than the measurement accuracy in the normal measurement mode ,
A flow rate sensor that outputs an electrical signal corresponding to the gas flow rate in the flow path;
A microcomputer for obtaining a flow rate according to an electrical signal from the flow sensor;
A peripheral circuit of the microcomputer, when the integrated amount by integrating the electric signal inputted from the simple measurement mode at the flow rate sensor has reached a predetermined amount, the for the transition from the simplified measurement mode to the high speed measurement mode A trigger signal generating circuit for generating one trigger signal;
A drive circuit for shifting the mode from the simple measurement mode to the high-speed measurement mode when the first trigger signal is generated by the trigger signal generation circuit ;
In the high-speed measurement mode, a value obtained by calculating at least one of the waveform frequency and amplitude from at least one waveform of the measured gas flow rate and gas pressure, or an operation indicating at least one state of the waveform frequency and amplitude Based on the results, the characteristics according to the vibration of the adjustment spring of the governor, and the characteristics according to the vibration due to the compressibility of the nozzle holder, whether the gas instrument having a governor is used or not. A measuring apparatus for judging whether or not a gas appliance is used . The microcomputer inputs a first trigger signal from the trigger signal generation circuit, and transmits an instruction signal to shift the mode from the simple measurement mode to the high-speed measurement mode to the drive circuit,
The measurement apparatus according to claim 1, wherein the drive circuit inputs an instruction signal from the microcomputer and shifts the mode from the simple measurement mode to the high-speed measurement mode . The measurement apparatus according to claim 1, wherein the drive circuit receives the first trigger signal from the trigger signal generation circuit and shifts the mode from the simple measurement mode to the high-speed measurement mode . Switch means for inputting a first trigger signal from the trigger signal generating circuit to be turned on;
The measurement apparatus according to claim 3, wherein the microcomputer is supplied with a power supply voltage when a first trigger signal is output from the trigger signal generation circuit and the switch unit is turned on. The trigger signal generation circuit integrates electric signals input from the flow rate sensor in the simple measurement mode, and a first trigger for shifting from the simple measurement mode to the high-speed measurement mode when the integrated amount reaches a predetermined amount. Generate a signal,
The microcomputer shifts from the high-speed measurement mode to the normal measurement mode after at least one of a gas flow rate and a gas pressure is detected at a measurement interval every second predetermined time for a specific time in the high-speed measurement mode. Generate a trigger signal
When the first trigger signal is generated from the trigger signal generation circuit, the drive circuit shifts the mode from the simple measurement mode to the high-speed measurement mode, and when the second trigger signal is generated from the microcomputer, The measurement apparatus according to any one of claims 1 to 4, wherein the mode is shifted from the high-speed measurement mode to the regular measurement mode . When the microcomputer determines that a flow rate exceeding a predetermined value is not detected based on an electrical signal from the flow rate sensor in the normal measurement mode, the microcomputer generates a third trigger signal for shifting from the normal measurement mode to the simple measurement mode. Let
6. The drive circuit according to claim 1 , wherein when the third trigger signal is generated from the microcomputer, the drive circuit shifts the mode from the normal measurement mode to the simple measurement mode. The measuring device described. The heater voltage in the simple measurement mode is made smaller than the heater voltage in the regular measurement mode when the flow rate sensor is a thermal type, according to any one of claims 1 to 6. The measuring device described. The measurement apparatus according to claim 1 , wherein a measurement interval in the high-speed measurement mode is shorter than a measurement interval in the regular measurement mode . In case the flow sensor is a thermal type, a heater voltage of the high-speed measurement mode, to any one of claims 1 to 8, characterized in that it is smaller than the heater voltage of the normal measurement mode The measuring device described. The measurement apparatus according to claim 1, wherein the trigger signal generation circuit includes an integration circuit .

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