JP3958658B2 - Flow rate measuring apparatus and control method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a flow rate measuring device and a control method.
[0002]
[Prior art]
A sound wave having a high frequency, such as an ultrasonic wave, is transmitted from the transmitter to the fluid to be measured and is received by the receiver, and the propagation time or propagation speed or single wave of the sound wave at that time is received. In a so-called ultrasonic propagation type flow measuring device that measures the around propagation cycle and measures the flow rate or flow velocity of the fluid to be measured based on the measurement result, generally, a sound wave other than the sound wave for measurement, Approximate vibrations and the like are mixed from the outside and become noise related to the measurement of flow rate or flow velocity, which may reduce the measurement accuracy. Alternatively, with the inside of the flow rate measuring device as the source, noise due to the mechanical mechanism and noise due to operation or malfunction of the electronic circuit for signal processing are mixed into the sound wave received by the receiver. In some cases, the measurement accuracy may be reduced.
[0003]
As a measure for improving or eliminating such a decrease in measurement accuracy due to noise contamination or internal malfunction of the flow measurement device, there are disturbance sound waves that cause noise other than measurement sound waves, Set to use sound waves with a frequency other than the frequency of sound waves that are generally assumed to be filtered and removed, or to be mixed into the flow measurement device as noise from the environment where the flow measurement device is installed. I think that.
[0004]
[Patent Document 1]
JP 2001-41792 A (paragraphs 0002 to 0029)
[0005]
[Problems to be solved by the invention]
In practice, however, noise is a so-called disturbance, so in various usage environments in which a flow rate measuring device such as a gas meter is installed, the flow rate and flow velocity are different from the expected frequency. There is also a probability that a frequency close to that of the sound wave used in the case will be generated. This is because the use environment in which the flow rate measuring device is used can be various as described above. Therefore, it has been difficult to completely prevent a decrease in measurement accuracy due to noise in the conventional flow rate measuring device.
[0006]
In addition, there is a problem that it is unavoidable that the measurement accuracy is lowered due to the difficulty in removing or avoiding noise.
[0007]
The present invention has been made in view of such problems, and its purpose is to automatically detect that an environment where a flow rate measuring device such as a gas meter is installed is an environment in which noise is frequently generated by a simple method. In addition, another object is to realize a flow rate measuring device capable of issuing an alarm to that effect and a control method for controlling the operation thereof.
[0008]
In addition, it is possible to reliably detect that noise from the outside or an erroneous signal due to an internal malfunction of the flow rate measuring device is mixed in the measurement using a simple method, and that is due to the noise or erroneous signal at that time. An object of the present invention is to realize a flow rate measuring device capable of avoiding a decrease in measurement accuracy of a flow rate or a flow velocity and a control method for controlling the operation thereof.
[0009]
[Means for Solving the Problems]
  The first flowmeter device according to the present invention has a transmitting means and a receiving means, and propagates a sound wave from the transmitting means to the fluid to be measured and receives it by the receiving means. Sampling to measure time or propagation speed or sing-around propagation period is performed at every predetermined sampling period, and the flow rate or flow velocity of the fluid is measured based on the propagation time or propagation speed or sing-around propagation period of the sound wave. A flow rate measurement device comprising a flow rate measurement device comprising a flow rate measurement means, wherein the reception means is also activated during a non-sampling period in which the sampling is suspended.Make it possible to receive sound waves at predetermined intervals,When a sound wave having a frequency within a frequency band that may cause noise in the measurement of the flow rate or flow velocity of the fluid is received by the receiving unit during the non-sampling period, it is detected and the sound wave is detected until a predetermined period and / or a predetermined number of times. When a sound wave in a frequency band that can become noise is repeatedly detected, noise determination control means for determining that noise is generated is further provided,Once noise is detected, the sound wave is received frequently by setting the period in which the sound wave can be received for at least a predetermined time thereafter to be shorter than the predetermined period before the noise is detected. It is characterized by making it possible. As described above, once noise is detected, the sound can be received frequently thereafter, so that noise can be detected more reliably.
[0010]
In the first flow rate measuring device according to the present invention, sound waves having a frequency within a frequency band that can be noise in the measurement of the flow rate or the flow rate of the fluid are mixed during a non-sampling period that does not interfere with the measurement of the flow rate or the flow rate. Is determined based on the reception state of the receiving means. That is, when a sound wave having a frequency within a frequency band that may cause noise in measurement of the flow rate or flow velocity of the fluid is received by the receiving unit during the non-sampling period, the noise determination control unit detects it, and When a sound wave having a frequency within a frequency band that can be the noise is repeatedly detected for a predetermined period and / or a predetermined number of times, it is determined that noise is generated. In addition, if a sound wave having a frequency within the frequency band that can be the noise in less than a predetermined period or less than a predetermined number of times is not detected, it is appropriate to determine that there is temporary noise contamination. In this case, it is not determined that noise is generated.
[0011]
The above-mentioned “when a sound wave having a frequency within a frequency band that can be noise up to a predetermined period and / or a predetermined number of times is repeatedly detected” refers to a frequency band within a frequency band that can be noise continuously over a predetermined period. "When a sound wave of a frequency is repeatedly detected" or "When a sound wave of a frequency within a frequency band that can be noise is repeatedly detected for a predetermined number of times" or "Detection is temporarily interrupted in the middle However, if the integrated value of the number of detections of sound waves having a frequency within the frequency band that can cause noise reaches a predetermined number of times, or “within a frequency band that can become noise continuously for a predetermined number of times within a predetermined period. If a sound wave with a frequency of 2 is repeatedly detected, or “even if the detection is temporarily interrupted in the middle of the It goes without saying integrated value of the number of times of detecting the waves is one that can take aspects, such as when "reaches a predetermined number of times.
[0013]
Alternatively, for example, when the receiving means receives a sound wave, the signal corresponding to the received sound is amplified and output, so that the sound wave can be received at all times. When the signal output from the means is a signal similar to a signal corresponding to a flow rate equal to or higher than a predetermined flow rate, a sound wave having a frequency within a frequency band that can be detected and become noise is detected by the flow measurement device. It may be determined that the problem occurs in the surrounding environment. Thus, the sound wave receiving means (and the circuit system, etc., from receiving the sound wave to amplifying and outputting the signal) is a voltage amplification type element and circuit system, etc., while having low power consumption. By making it possible to always receive sound waves, it is possible to always reliably detect noise while taking advantage of its low power consumption.
[0014]
Further, it is preferable that the noise determination control means includes an alarm means for outputting information indicating that the noise is generated or an alarm for notifying the noise when it is determined that the noise is generated.
[0015]
In addition, if a signal corresponding to a predetermined flow rate value or flow rate temporal transition pattern is output from the flow rate measuring means as not being in a predetermined use state as the flow rate measuring device, the signal is ignored. Then, it is possible to further include a flow rate measurement operation control means for controlling the flow rate measurement operation in the flow rate measurement device so as to measure the flow rate or the flow velocity.
[0016]
Further, when the noise determination control means further determines that the noise is generated, the noise determination control means increases the intensity of the output of the sound wave propagated from the transmitter to the fluid to be measured, and The signal / noise ratio in the measurement of the flow rate or flow velocity may be increased. Thus, by automatically detecting the occurrence of noise and increasing the signal / noise ratio, it is possible to avoid a reduction in measurement accuracy due to the noise. Alternatively, it is also desirable to increase the intensity of the sound wave output from the transmitter in accordance with the noise level (dB or the like).
[0017]
Such flow measurement operation control means can be attached to the flow measurement device separately from the above-described noise determination control means (independently). That is, the second flow rate measuring device according to the present invention has a transmitting means and a receiving means, and propagates a sound wave from the transmitting means to the fluid to be measured and receives it by the receiving means. Sampling to measure the propagation time or propagation speed or sing-around propagation period of the sound is performed every predetermined sampling period, and based on the propagation time or propagation speed or sing-around propagation period of the sound wave, the flow rate or flow velocity of the fluid is determined. A flow rate measuring device having a flow rate measuring means for measuring, and a signal corresponding to a predetermined flow rate value or a temporal transition pattern of the flow rate that the flow rate measuring device cannot be in a predetermined use state is measured. If it is output from the means, the signal is ignored and the flow rate measuring device is measured so as to measure the flow rate or flow velocity. Those having a flow rate measuring operation control means for controlling the kicking operation of measuring the flow rate or flow rate.
[0018]
In the second flow rate measuring device according to the present invention, the flow rate measuring operation control means is a signal corresponding to a predetermined flow rate value or a temporal transition pattern of the flow rate that the flow rate measuring device cannot be in a predetermined use state. Is output from the flow rate measuring means, the flow rate or flow rate measurement operation in the flow rate measuring device is controlled so that the signal is ignored and the flow rate or flow rate is measured. In other words, the frequency of noise that may be mixed is often unpredictable depending on the environment where the flow measurement device is actually installed. Whether or not the vibration intensity or amplitude is not possible in the predetermined use state of the flow rate measuring device does not depend on the installation environment, and can be reliably assumed in advance. For example, in the case of a gas meter, since the maximum flow rate that can be measured for each number is determined in advance, a signal corresponding to the flow rate exceeding the maximum flow rate should be output from the flow rate measurement means under normal use conditions. Is impossible. Therefore, conversely, when a signal that is not possible under such normal use conditions is output, it is highly appropriate to determine that noise is mixed or an erroneous signal has occurred. Therefore, in such a case, the flow rate measurement operation control means controls the flow rate or flow rate measurement operation in the flow rate measurement device so that the signal at that time is ignored and the flow rate or flow rate is measured.
[0019]
In this way, by ignoring signals with a high probability of being noise or erroneous signals, the flow rate or flow rate measurement is performed to improve or eliminate the decrease in flow rate or flow rate measurement accuracy caused by noise or erroneous signal mixing. It becomes possible.
[0020]
The flow measurement operation control means obtains a signal obtained by sampling before the sampling of the ignored signal and / or sampling after the sampling of the ignored signal instead of the ignored signal. Controlling the flow rate or flow velocity measurement operation in the flow rate measuring device so that the flow rate or the flow velocity is measured using the generated signal as a signal obtained at the sampling timing of the ignored signal Is possible.
[0021]
Here, “a signal obtained by sampling prior to the sampling of the ignored signal and / or a signal obtained by sampling after the sampling of the ignored signal is obtained at the sampling timing of the ignored signal. "Use as a signal that is considered to be a signal that has been used" means "use a signal obtained by sampling prior to the sampling of the neglected signal" or "use by sampling after the sampling of the neglected signal". The signal obtained by sampling prior to the sampling of the neglected signal and the signal obtained by sampling after the sampling of the neglected signal, and the neglected Calculated based on signals obtained by sampling prior to signal sampling Calculating a mean value of the flow rate or flow rate than the sampling of the amount or flow rate as the ignored signal is calculated based on a signal obtained in the subsequent sampling "that is that it is possible embodiment of such.
[0022]
In more detail, the flow measurement operation control means temporarily stores a signal output from the flow measurement means over a predetermined number of sampling times and uses it instead of the ignored signal. You may make it control the measurement operation | movement of the flow volume or flow velocity in the said flow measuring device so that the said flow volume or the said flow velocity may be measured.
[0023]
Further, the fluid is a gas used as a fuel or an energy source, and the flow rate measuring means measures a flow rate or an integrated flow rate of the gas so as to substantially function as a gas meter. Is possible. That is, the present invention is suitable for a gas meter that is supposed to be used in various installation environments.
[0024]
The above-described noise determination control means or flow rate measurement operation control means is a control built in a dedicated LSI or printed wiring board for controlling the operation of a built-in gas meter such as a so-called ultrasonic propagation microcomputer meter. As a circuit, the control method according to the present invention is realized by using a control circuit which is manufactured as an industrial product independent of the main body of the flow measuring device such as the micrometer and attached to the main body of the micrometer. It is also possible to make it.
[0025]
  That is, a first control method according to the present invention includes a transmitting unit and a receiving unit, and propagates a sound wave from the transmitting unit to a fluid to be measured and receives it by the receiving unit. Sampling to measure the propagation time or propagation speed or sing-around propagation period is performed every predetermined sampling period, and the flow rate or flow velocity of the fluid is measured based on the propagation time or propagation speed or sing-around propagation period of the sound wave. A flow rate measuring device including a flow rate measuring device including a flow rate measuring unit for performing the reception unit during a non-sampling period in which the sampling is suspended.Make it possible to receive sound waves at predetermined intervals,When a sound wave having a frequency within a frequency band that may cause noise in the measurement of the flow rate or flow velocity of the fluid is received by the receiving unit during the non-sampling period, it is detected and the sound wave is detected until a predetermined period and / or a predetermined number of times. If sound waves in the frequency band that can be noise are repeatedly detected, determine that noise is occurring,Once noise is detected, the sound wave is received frequently by setting the period in which the sound wave can be received for at least a predetermined time thereafter to be shorter than the predetermined period before the noise is detected. It makes it possible.
[0027]
In addition, when the flow rate measuring device includes an alarm unit and it is determined that noise is generated, the alarm unit outputs information indicating that the noise is generated or an alarm for notifying the information. May be.
[0028]
Alternatively, the receiving means is always in a state capable of receiving a sound wave, and when receiving the sound wave, a signal corresponding to the sound wave is amplified and outputted, and the voltage level of the signal amplified and outputted from the receiving means Is detected as a sound wave having a frequency within a frequency band that can be a noise when the voltage is equal to or higher than a predetermined voltage level, and a sound wave having a frequency within the frequency band that can be the noise is repeatedly detected for a predetermined period and / or a predetermined number of times. It may be determined that noise has occurred.
[0029]
In addition, if a signal corresponding to a predetermined flow rate value or flow rate temporal transition pattern is output from the flow rate measuring means as not being in a predetermined use state as the flow rate measuring device, the signal is ignored. Then, the flow measurement operation in the flow measurement device may be controlled so as to measure the flow rate or flow velocity.
[0030]
The second control method according to the present invention includes a transmitting means and a receiving means, and propagates sound waves from the transmitting means to the fluid to be measured and receives them by the receiving means. Sampling to measure the propagation time or propagation speed or sing-around propagation period is performed every predetermined sampling period, and the flow rate or flow velocity of the fluid is measured based on the propagation time or propagation speed or sing-around propagation period of the sound wave. Control method for controlling the measurement operation of the flow rate or flow velocity in the flow rate measuring device provided with the flow rate measuring means, and the flow rate value or the flow time that is predetermined as the flow rate measuring device cannot be in a predetermined use state If a signal corresponding to the pattern of the static transition is output from the flow rate measuring means, the signal is ignored and the flow rate or flow rate is ignored. And controls the measurement operation of the flow rate or flow velocity at the flow rate measuring device to perform the measurement of the flow velocity.
[0031]
More specifically, instead of the ignored signal, a signal obtained by sampling before the ignored signal and / or a signal obtained by sampling after the ignored signal sampling. Is used as a signal obtained at the sampling timing of the neglected signal, and the flow rate or flow velocity measurement operation in the flow rate measurement device is controlled to measure the flow rate or the flow velocity. Good.
[0032]
Further, the signal output from the flow rate measuring means for a predetermined number of sampling times is temporarily stored, and the flow rate or the flow velocity is measured in place of the neglected signal. You may make it control the measurement operation | movement of the flow volume or flow velocity in a measuring device.
[0033]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0034]
FIG. 1 shows a schematic configuration of a gas meter which is a flow rate measuring apparatus according to an embodiment of the present invention. In addition, since the control method which concerns on embodiment of this invention is embodied by being integrated and used for this gas meter, they are demonstrated collectively below.
[0035]
This gas meter is installed in each house such as a general house or building where gas can be used, and is equipped with a metering function (measurement) function for gas flow integrated value (gas consumption), safety function, automatic meter reading function, etc. Thus, in order to measure the flow rate value of the gas flowing in the flow path 21, the ultrasonic wave propagation time measuring unit 20 having ultrasonic sensors 22A and 22B for propagating predetermined ultrasonic waves to the gas, the flow rate value calculating unit 30, and the control The circuit 40, the flow value integration unit 50, the flow integration value display control unit 61, the flow integration value display unit 62, the basic operation control unit 70, and the battery 80 are provided as main units for performing flow measurement. ing.
[0036]
Furthermore, a seismic device 91, a pressure sensor 92 and a temperature sensor 93 disposed downstream of the flow path 21, a shut-off valve 94 disposed upstream of the flow path 21, and a shut-off valve drive mechanism 95 that drives the shut-off valve 94. , As well as a security unit 90 connected directly or indirectly to execute a predetermined security function, a communication unit 100 for transmitting / receiving meter reading information such as a flow rate integrated value to a management center of a gas company, A microcomputer stop detection unit 110 for monitoring the runaway of the microcomputer constituting the basic operation control unit 70 for performing various controls for performing flow rate measurement and safety functions as a typical gas meter, and connected to the microcomputer stop detection unit 110 Start-up / reset unit 120, pulsation occurrence determination unit 130 that determines that pulsation has occurred in gas, and alarm unit 1 that issues an alarm to the outside Has a 0 and.
[0037]
In addition to this, various devices that are generally used as a gas meter, such as a return switch for executing shut-off return, a microleakage detection device (all not shown), and the like are also provided. Since these structures are not directly related to the main structure of the present invention, their description is omitted.
[0038]
The ultrasonic sensors 22A and 22B of the ultrasonic propagation time measuring unit 20 propagate ultrasonic waves from the upstream side to the downstream side at a predetermined frequency per measurement duty for the gas flowing through the flow path 21, Propagation from the downstream side to the upstream side is repeated alternately at a predetermined timing, and each of them has a function as a transmitter and a function as a receiver. That is, when the ultrasonic sensor 22A functions as a transmitter to transmit an ultrasonic wave having a predetermined frequency, the ultrasonic sensor 22B functions as a receiver to receive an ultrasonic wave having a predetermined frequency band and corresponding electric power. It is set to output a signal. These ultrasonic sensors 22 </ b> A and 22 </ b> B are connected to a propagation time measurement / control unit 23 via a transmission / reception circuit 24.
[0039]
The propagation time measurement / control unit 23 is configured to transmit the forward propagation time T1 when the ultrasonic wave is propagated from the upstream side to the downstream side based on the electrical signals output from the ultrasonic sensors 22A and 22B, and from the downstream side. The reverse propagation time T2 when the sound wave is propagated to the upstream side is measured. The propagation time measurement / control unit 23 controls the switching of the ultrasonic wave propagation direction and the repetition of the ultrasonic wave transmission, and the ultrasonic sensors 22A and 22B per one sampling timing. In order to perform such a function, a function of oscillating an electric signal for causing one of them to be oscillated and a function of amplifying an electric signal output in response to an ultrasonic wave received by the other are provided. The timer (not shown) for timekeeping used for the is also provided. The basic hardware for measuring the flow rate of the propagation time measurement / control unit 23, its control logic, and the like are the same as the conventional general ones.
[0040]
Each time the propagation time measurement / control unit 23 measures the propagation times T1 and T2, the flow rate value calculation unit 30 obtains the flow velocity value v at that time based on the propagation times T1 and T2, and the flow velocity value v The instantaneous gas flow rate value Q at the measurement duty at that time is obtained. As for the flow rate value calculation unit 30 as well, conventional general components can be used as basic hardware for measuring the flow rate and its control logic. The ultrasonic sensors 22A and 22B, the propagation time measurement / control unit 23, and the transmission / reception circuit 24 substantially function as a main part of the flow rate measuring means.
[0041]
The flow rate value integration unit 50 obtains an average flow rate value Qa to be integrated based on the measurement result of the flow rate value Q measured over a plurality of sampling times by the flow rate value calculation unit 30, and calculates the average flow rate value Qa. By adding the data to the accumulated flow rate value ΣQ stored so far, the accumulated flow value ΣQ is obtained. More specifically, the flow rate value integrating unit 50 takes an average value of two measurement results, for example, the latest flow rate value Qn and the previous flow rate value Qn-1 as the average flow rate value Qa. can do. However, it goes without saying that the present invention is not limited to such a calculation method. For example, the average flow rate value Qa is obtained by taking the average value of the measurement results for a total of three times, the latest flow rate value Qn, the previous flow rate value Qn-1 and the previous flow rate value Qn-2. May be calculated. As described above, by integrating the flow rate value ΣQ based on the measurement results of the flow rate values Qn, Qn-1... Measured over a plurality of sampling times, the influence of pulsation and the like is eliminated and the flow rate integration is performed. The accuracy of the value ΣQ can be ensured.
[0042]
The flow rate integrated value display control unit 61 causes the flow rate integrated value display unit 62 to display the flow rate integrated value ΣQ integrated by the flow rate value integrating unit 50. The flow rate integrated value display unit 62 is formed by using, for example, a liquid crystal panel, and is controlled by the flow rate integrated value display control unit 61 so that the value of the flow rate integrated value ΣQ is numerically displayed by, for example, an 8-segment method. Yes.
[0043]
The basic operation control unit 70 is based on a program executed by the flow value calculation unit 30, the flow value integration unit 50, the flow integration value display control unit 61, etc. stored in a ROM (Read Only Memory; not shown), for example. This is a so-called microcomputer that controls the basic operation of the gas meter as a whole flow measuring device. The basic operation control unit 70 is the same as that used in a so-called microcomputer gas meter of a general ultrasonic propagation method.
[0044]
The battery 80 supplies power for operating the entire gas meter, and a battery having a life of about 7 to 10 years, such as a lithium battery, can be suitably used.
[0045]
The seismoscope 91 detects the occurrence of an earthquake by detecting the occurrence of strong vibrations of a predetermined intensity or higher.
[0046]
The pressure sensor 92 measures the pressure P of the gas flowing in the flow path 21. The pressure sensor 92 includes, for example, a piezoelectric film sensor that generates a voltage corresponding to distortion caused by pressure. The pressure P measured by the pressure sensor 92 is output to the pulsation generation determination unit 130 and the security unit 90, for example.
[0047]
The temperature sensor 93 measures the temperature of the gas flowing through the flow path 21. The temperature sensor 93 is disposed, for example, in the flow path 21 and includes a thermoelectric sensor (thermocouple), a resistance sensor (metal resistance thermometer), a thermistor sensor, a semiconductor sensor, and the like. The electric signal corresponding to the temperature is set to be output. An electrical signal corresponding to the temperature measured by the temperature sensor 93 is output to the security unit 90, for example.
[0048]
Based on the signal from the seismic sensor 91, the pressure P even measured by the pressure sensor 92, and the temperature measured by the temperature sensor 93, the security unit 90 determines whether the gas usage state or the environment in which the gas meter is installed is It is determined whether or not the gas is in a dangerous state. If it is determined that the gas is in a dangerous state, a valve drive signal is output and the cutoff valve drive mechanism 95 drives the cutoff valve 94. A predetermined security operation such as shutting off the gas supply by closing the valve is performed.
[0049]
The communication unit 100 executes a communication function for transmitting / receiving information such as meter reading data to / from a gas company management center via a communication line (not shown) such as a telephone line or a dedicated line. The communication unit 100 includes, for example, a T-NCU (Terminal Network Control Unit) which is a terminal modem device provided exclusively for a gas meter, although not shown, and a communication line (not shown) via the T-NCU. ) Is set to be accessible. In addition, the communication unit 100 accesses the gas meter from the management center side of the gas company, and remotely controls the opening / closing operation of the shut-off valve 94 and the gas usage measurement operation, and monitors the state of the gas meter. It is also possible to set.
[0050]
The microcomputer stop detection unit 110 monitors troubles such as runaway or stop of the microcomputer constituting the basic operation control unit 70. The activation / reset unit 120 performs activation and reset.
[0051]
The alarm unit 140 includes a warning lamp (not shown) made of, for example, a light emitting diode, and the above-described security unit 90 makes the gas use state or the environment where the gas meter is installed dangerous. Is set to perform blinking display with a predetermined blinking pattern as an alarm to that effect. In addition, when it is determined that noise is generated by the noise determination control unit of the control circuit as will be described later, an alarm indicating that the above-described dangerous state is present as an alarm to that effect It is set to perform blinking display so that it can be distinguished by different predetermined blinking patterns. The alarm unit 140 can transmit information indicating that a dangerous state has occurred via the communication unit 100 or information indicating that noise has occurred to the management center of the gas company. It is desirable to be set as follows.
[0052]
The control circuit 40 includes a noise determination control unit 41 and a flow rate measurement operation control unit 42.
[0053]
The noise determination control unit 41 performs either one of the ultrasonic sensor 22A or the ultrasonic sensor 22B (or both in some cases) even during a non-sampling period in which sampling for flow rate measurement is suspended. The frequency in the frequency band that can be a noise for gas flow measurement (in other words, the ultrasonic sensor 22A and the ultrasonic sensor are used to measure the flow rate) by causing the transmitter / receiver circuit 24 to operate as an ultrasonic receiver and to operate. When the ultrasonic sensor 22A or the ultrasonic sensor 22B receives the ultrasonic wave in the non-sampling period, the ultrasonic wave in the frequency band approximated to the ultrasonic frequency set to be transmitted to and received from the ultrasonic wave 22B is received. , And detect the frequency within the frequency band that may be the noise until the predetermined period elapses or the predetermined number of times. When the sound wave is detected is to determine that the noise is mixed (generated).
[0054]
Here, the presence of noise means that, in other words, the place where the gas meter is installed is in an environment where it is easy to give noise to the gas meter. Therefore, when it is determined that the noise is mixed (decreased), it is highly probable that the installation environment of the gas meter is an external trouble factor. An alarm is notified to a gas management company (not shown), a meter reader, etc., for example, the frequency of the ultrasonic wave used for flow rate measurement is changed to a frequency different from that of the frequency band used so far. It is desirable to be able to take action. Therefore, when the noise determination control unit 41 determines that noise is mixed, the noise determination control unit 41 controls the alarm unit 140 to issue a warning that noise is mixed. At the same time, via the communication unit 100, for example, the central management system of the gas management company is notified of information indicating that the gas meter is frequently mixed with noise.
[0055]
Thus, according to the noise determination control unit 41, during the non-sampling period of flow measurement, it is possible to detect the generation (mixing) of noise and output an alarm and information to that effect, and as a result, the gas meter Automatically detects that the location where the is installed is in an environment where noise is likely to be applied to the gas meter, and automatically notifies the gas management company, meter reader, general user, etc. be able to.
[0056]
It should be noted that the ultrasonic wave propagation time measurement unit 20, the main part of which is composed of the ultrasonic sensors 22 A and 22 B, the transmission / reception circuit 24, and the propagation time measurement / control unit 23, is intermittent at a predetermined cycle during the non-sampling period of flow rate measurement. In the non-sampling period, the noise determination control unit 41 can receive sound waves at a relatively low frequency, for example, once every 12 hours. Once the noise is detected, after that, for example, for a predetermined period such as one day, the period for making the sound wave receivable is shorter than the predetermined period before the noise is detected. Then, for example, once every 30 minutes, etc., it may be possible to detect noise more reliably by making the sound wave receivable frequently.
[0057]
Alternatively, the ultrasonic sensors 22A and 22B, the transmission / reception circuit 24, and the propagation time measurement / control unit 23 are in a state in which ultrasonic waves can always be received during the non-sampling period. By making the voltage amplification type element and circuit system that amplifies and outputs the voltage, while keeping the characteristic of low power consumption due to the voltage amplification type, always keeping the noise detectable, even once When a signal corresponding to noise is detected, it is determined that noise has occurred, and it is possible to operate with low power consumption, but more reliably detect disturbance noise and vibration. It becomes possible.
[0058]
Here, as a logic that is a criterion for determining that noise is occurring, (1) when a sound wave having a frequency within a frequency band that can be noise is continuously detected over a predetermined period, or (2) When a sound wave having a frequency within a frequency band that can be noise is repeatedly detected for a predetermined number of times, or (3) Even within the frequency band that can be noise even if detection is temporarily interrupted in the middle When the integrated value of the number of times of detecting the sound wave of the frequency reaches the predetermined number of times, or (4) the sound wave of the frequency within the frequency band that can become noise is continuously detected over the predetermined number of times within the predetermined period. Or (5) Even if the detection is temporarily interrupted, the integrated value of the number of times of detecting the sound wave of the frequency within the frequency band that may become noise within the predetermined period reaches the predetermined number. Etc., make determination that the noise occurs, it is possible aspect that. It goes without saying that various other determination logics may be employed.
[0059]
The flow rate measurement operation control unit 42 receives a signal corresponding to a predetermined flow rate value or flow rate temporal transition pattern as an ultrasonic propagation time measurement unit that the gas meter cannot be in a normal use state or a normal operation state. When the signal is output from 20, the flow meter is controlled so that the signal is ignored and the flow value is calculated.
[0060]
More specifically, the flow measurement operation control unit 42 ignores an abnormal signal as described above when output from the ultrasonic propagation time measurement unit 20, but instead of the ignored signal, A signal obtained by sampling before the sampling of the ignored signal and / or a signal obtained by sampling after the sampling of the ignored signal is regarded as a signal obtained at the sampling timing of the ignored signal. Use it to calculate the measured flow rate.
[0061]
Here, as a signal used in place of the ignored signal, (1) a signal obtained by sampling before the ignored signal is used, or (2) sampling after the ignored signal sampling. Or (3) neglect using both the signal obtained by sampling before the sampling of the ignored signal and the signal obtained by sampling after the sampling of the ignored signal. The average value of the flow rate calculated based on the signal obtained by sampling before the sampling of the corrected signal and the flow rate calculated based on the signal obtained by sampling after the sampling of the ignored signal is calculated. Thus, a more specific aspect such as using the average value is possible. Instead of such a neglected signal, the signal before and after the sampling (that is, information on the flow rate measurement value carried by the signal) is, for example, a storage element (not shown) set to function as a pre-buffer. If the signal from the ultrasonic wave propagation time measuring unit 20 is ignored, the information temporarily stored in the storage element is read out and the signal is ignored. Instead, it is possible to calculate the flow rate value.
[0062]
It should be noted that both the signal obtained by sampling prior to the sampling of the ignored signal and the signal obtained by sampling after the sampling of the ignored signal are used for sampling prior to the sampling of the ignored signal. When calculating the average value of the flow rate calculated based on the obtained signal and the flow rate calculated based on the signal obtained by subsequent sampling rather than sampling the ignored signal, and using the average value, At least a temporal time lag until a signal at a later sampling is obtained rather than a sampling of a neglected signal will occur during the flow rate calculation process, but it is actually a very small temporal time lag. There is no substantial problem with flow measurement.
[0063]
As described above, the flow measurement operation control unit 42 determines the frequency of noise that may be mixed in the flow measurement process depending on the environment where the gas meter is actually installed. In many cases, it is unpredictable whether the noise will occur, but regarding the intensity and amplitude of the noise vibration, the vibration and intensity that are not possible in the specified use condition are external conditions such as the installation environment. Can be reliably assumed in advance without depending. For example, the gas meter has a predetermined maximum flow rate that can be measured for each number, so under normal operating conditions or when the gas meter is operating normally, a signal corresponding to the flow rate that exceeds the maximum flow rate is displayed. Since it is unlikely that it will be output from the flow measurement unit, conversely, if a signal that is not possible under such normal use conditions is output, there is a possibility that noise has entered or an erroneous signal has occurred. Is extremely high. Accordingly, the flow rate measurement operation in the gas meter is controlled by the flow rate measurement operation control unit 42 so as to perform the flow rate value calculation while ignoring the impossible signal, so that the flow rate measurement caused by noise mixing or an erroneous signal is performed. A decrease in accuracy can be reliably prevented.
[0064]
Next, operations of the noise determination control unit 41 and the flow rate measurement operation control unit 42 of the control circuit 40 will be described as operations of the gas meter according to the embodiment of the present invention. The other general operations such as the security function are the same as those in a general gas meter, and thus detailed description thereof is omitted.
[0065]
As shown in FIG. 2, during the sampling period (Y in S1), the ultrasonic sensors 22A and 22B of the ultrasonic propagation time measuring unit 20 perform the measurement duty once for the gas flowing through the flow path 21. Ultrasonic waves are propagated at a predetermined frequency. At this time, the propagation time measurement / control unit 23 switches the propagation direction of the ultrasonic wave every predetermined time according to a timer (not shown), and repeats this. Thereby, the ultrasonic sensors 22A and 22B alternately repeat the propagation of the ultrasonic waves from the upstream side to the downstream side and the propagation of the ultrasonic waves from the downstream side to the upstream side at a predetermined timing. An electrical signal corresponding to the gas flow rate is output. The propagation time measurement / control unit 23 receives electrical signals output from the ultrasonic sensors 22A and 22B via the transmission / reception circuit 24, and propagates sound waves from the upstream side to the downstream side based on the electrical signals. The information signal of the forward propagation time T1 and the information signal of the backward propagation time T2 when the sound wave is propagated from the downstream side to the upstream side are transmitted to the flow rate value calculation unit 30.
[0066]
The flow value calculation unit 30 receives the information signal of the propagation times T1 and T2 measured by the propagation time measurement unit 23, obtains the flow velocity value v at that time based on the propagation times T1 and T2, and further An operation of multiplying the flow rate coefficient k corresponding to the flow velocity value v is performed to obtain an instantaneous flow rate value Q of the gas at the measurement duty at that time, and this is transmitted to the flow rate value integrating unit 50 (S2).
[0067]
The flow value integration unit 50 receives the information of the flow value Q calculated by the flow value calculation unit 30 and temporarily stores it in a memory (not shown). Then, based on the measurement result of the flow value Q measured a plurality of times, an average flow value Qa to be integrated is obtained, and the data of the average flow value Qa is added to the accumulated flow value ΣQ stored so far. As a result, the integrated flow value ΣQ is obtained (S3). The flow rate integrated value ΣQ is displayed on the screen of the flow rate integrated value display unit 62 in place of the numerical value displayed so far (S4).
[0068]
Up to this point, the operation is to calculate the flow rate integrated value similar to that of a general ultrasonic propagation type gas meter, but the signal output from the ultrasonic propagation time measuring unit 20 is in parallel with the flow value calculating unit being sent. Then, it is also sent to the flow rate measurement operation control unit 42.
[0069]
As shown in FIG. 5, the flow rate measurement operation control unit 42 has a flow rate value or a temporal transition pattern of the flow rate that is predetermined as a gas meter that cannot be in a normal use state or a normal operation state. Is output from the ultrasonic propagation time measuring unit 20 (Y in S5), the signal is ignored (S6), and instead of the ignored signal, sampling of the ignored signal is performed. The signal obtained in the previous sampling and / or the signal obtained in the subsequent sampling rather than the sampling of the ignored signal is regarded as the signal obtained in the sampling timing of the ignored signal, and the flow rate The operations of the flow rate value calculation unit 30 and the flow rate value integration unit 50 are controlled so as to perform the calculation of the value Q and the integration thereof. Then, the calculated integrated flow value ΣQ is displayed on the screen of the integrated flow value display unit 62 instead of the numerical value displayed so far (S8).
[0070]
However, the signal output from the ultrasonic propagation time measuring unit 20 corresponds to a predetermined flow rate value or a temporal transition pattern of the flow rate that is not possible in the normal use state or normal operation state of the gas meter. If not (in other words, if the signal is normal; N in S5), the flow rate integrated value ΣQ is calculated by the above-described normal flow rate Q measurement method and integration method (S3 in FIG. 2). S4).
[0071]
When it is in the non-sampling period (N in S1 in FIG. 2), the noise determination control unit 41 receives an ultrasonic wave in a frequency band that can become noise as shown in FIG. 3 (Y in S31). The flag of the number n of receptions of such noise is set to n + 1. If the value of the flag added by +1 is equal to or greater than a predetermined threshold value nth (= 100) such as 100 times (n ≧ nth; Y in S33), noise is generated. (S34), a warning to that effect is issued by the alarm unit 140 (S35) and transmitted to an external management company or the like via the communication unit 100 (S36). Then, the flag n is reset to 0 (n = 0; S37).
[0072]
Alternatively, when the ultrasonic propagation time measurement unit 20 is set to intermittently detect noise at a predetermined period during the non-sampling period for flow rate measurement, the noise determination control unit 41 performs the non-sampling period. (N in S1 in FIG. 2), as shown in FIG. 4, if there is reception of ultrasonic waves in a frequency band that may be noise (Y in S41), the flag up to that time is n = 0. In this case (Y in S42), the noise detection cycle is made shorter than before (S43), so that the noise detection frequency is increased so that the noise can be detected more reliably.
[0073]
Then, the flag of the noise reception count n is set to n + 1 (S44). When the value of the flag obtained by adding +1 is equal to or greater than a predetermined threshold value nth (= 100) such as 100 times as the noise detection continues (n ≧ nth) ; Y of S45), it is determined that noise has occurred (S46), an alarm to that effect is issued by the alarm unit 140 (S47), and transmitted to an external management company or the like via the communication unit 100 (S48). ). Then, the flag n is reset to 0 (n = 0; S49).
[0074]
As described above, in the gas meter of the present embodiment, it is possible to automatically detect that the environment where the gas meter is installed is an environment in which noise is frequently generated by a simple method, and further to issue an alarm to that effect. it can. In addition, it is ensured by simple methods that noise from the outside and an erroneous signal due to internal malfunction of the gas meter are mixed in the flow measurement, and without any adverse effect or inconvenience on the flow measurement. It is possible to prevent a decrease in flow rate measurement accuracy caused by noise or an erroneous signal at that time.
[0075]
In the above embodiment, the case where the present invention is applied to a gas meter that measures the flow rate of a gas used as a fuel or an energy source, which is assumed to be used in various installation environments, has been described. Needless to say, the application of the invention is not limited to this. In addition to a gas meter, it can be applied to a water and sewage meter, a power meter, a liquid fuel meter, and the like.
[0076]
Here, since the flow rate is inevitably calculated by multiplying the flow velocity by the cross-sectional area of the fluid to be measured, both the flow rate and the flow velocity can be measured by the flow measurement device according to the present invention. is there. On the basis of this, in the present specification, what measures the flow velocity is also called a flow rate measuring device. Therefore, the present invention can be applied not only to a device for measuring a flow rate such as a gas meter, but also to a device for measuring a flow velocity such as an air flow or a wind in a predetermined place.
[0077]
In addition, the noise determination control unit 41 and the flow rate measurement operation control unit 42 are built in a gas meter such as a so-called ultrasonic propagation type microcomputer meter, and are configured as a control circuit including a dedicated LSI or the like for performing operation control. Apart from the main body of the flow rate measuring device such as the microcomputer meter, it is possible to make a control circuit that is manufactured as an industrial product independent of the main body and attached to the main body of the microcomputer meter.
[0078]
In addition to the ultrasonic propagation time measuring unit 20 that measures the flow rate by propagating ultrasonic waves to the gas in the manner described in the above embodiment, the ultrasonic sensors 22A and 22B emit light from one side. When the received ultrasonic wave is received on the other side, it is set to repeat the transmission of the return ultrasonic wave based on the reception, and the transmission / reception cycle of the return of the ultrasonic wave changes in accordance with the gas flow rate. Is used to measure the sing-around propagation period, which is the period of transmission and reception of the ultrasonic return, and based on the sing-around propagation period, to measure the flow rate of the gas to be measured at that time Needless to say, the present invention is also applicable to a sing-around propagation type flow rate measuring device.
[0079]
Further, when the noise determination control unit 41 further determines that noise is generated, the noise determination control unit 41 determines the intensity of the output of the sound wave propagated from the ultrasonic sensors 22A and 22B (transmitter) to the measurement target gas. It may be increased to increase the S / N (signal / noise) ratio in the measurement of the flow rate (or flow velocity). Alternatively, in this case, the degree of increase may be changed corresponding to the intensity of noise (dB or the like) detected during the non-sampling period.
[0080]
【The invention's effect】
  As explained above, the claims1 to 9The flow measuring device according to any one of claims 1 to 3, or claim10 to 18According to the control method described in any one of the above, when a sound wave having a frequency within a frequency band that may cause noise in the measurement of the flow rate or flow velocity of the fluid is received by the receiving unit during the non-sampling period, The determination control means detects it, and further determines that noise is occurring when a sound wave having a frequency within the frequency band that can be the noise is repeatedly detected for a predetermined period and / or a predetermined number of times.Once noise is detected, the sound wave can be received at least for a predetermined period, and the sound wave can be received at a shorter period than the predetermined period before the noise is detected. I made it possible.A flow measuring device capable of automatically detecting by a simple method that the environment in which a flow measuring device such as a gas meter is installed is an environment in which noise is frequently generated, and further issuing an alarm to that effect, and its There is an effect that a control method for controlling the operation can be realized.
[0081]
  In particular, the claims6 to 9The flow measuring device according to any one of claims 1 to15 to 18According to the control method described in any one of the above, the flow measurement operation control means corresponds to a predetermined flow value or a temporal transition pattern of the flow that the flow measurement device cannot be in a predetermined use state. When a signal is output from the flow rate measuring means, the flow rate or flow rate measurement operation in the flow rate measurement device is controlled so that the flow rate or flow rate is measured ignoring the signal. A simple method is used to reliably detect the presence of noise or an erroneous signal due to an internal failure of the flow measurement device from the outside, and the flow rate or flow velocity caused by the noise or erroneous signal at that time. It is possible to avoid a decrease in measurement accuracy.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of a gas meter which is a flow rate measuring device according to an embodiment of the present invention.
FIG. 2 is a flowchart showing a main part of a normal flow measurement process during a sampling period.
FIG. 3 is a flowchart showing a main part of a control process by a noise determination control unit when reception of ultrasonic waves in a frequency band that may become noise during a non-sampling period.
FIG. 4 is a flowchart showing a main part of a variation of a control process performed by a noise determination control unit when an ultrasonic wave in a frequency band that may become noise is received during a non-sampling period.
FIG. 5 is a flowchart showing a main part of a control process by a flow rate measurement operation control unit.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 20 ... Ultrasonic propagation time measurement part, 22A, 22B ... Ultrasonic sensor, 30 ... Flow rate value calculation part, 40 ... Control circuit, 41 ... Noise determination control part, 42 ... Flow rate measurement operation control part, 50 ... Flow rate value integration part , 61 ... Flow rate integrated value display control unit, 62 ... Flow rate integrated value display unit, 70 ... Basic operation control unit, 80 ... Battery, 100 ... Communication unit, 140 ... Alarm unit

Claims (18)

It has a transmitting means and a receiving means, and a sound wave is propagated from the transmitting means to the fluid to be measured and received by the receiving means, and at that time, the propagation time or propagation speed of the sound wave or the sing-around propagation period is measured. And a flow rate measuring device including a flow rate measuring means for measuring a flow rate or a flow rate of the fluid based on a propagation time, a propagation speed, or a sing-around propagation cycle of the sound wave. And
A frequency within a frequency band that may cause noise when measuring the flow rate or flow velocity of the fluid by allowing the receiving means to receive a sound wave every predetermined period even during a non-sampling period in which the sampling is suspended. Is detected by the receiving means during the non-sampling period, and if a sound wave in the frequency band that can become the noise is repeatedly detected for a predetermined period and / or a predetermined number of times, noise is detected. Noise detection control means for determining that noise has occurred is further provided, and once the noise is detected, the noise detects a period in which the sound wave can be received for at least a predetermined time thereafter. The flow rate measuring device is characterized in that it is shorter than a predetermined cycle before being put into a state where sound waves can be received frequently . The noise judgment control unit, when it is determined that noise has occurred, claim characterized by comprising an alarm means for outputting an alarm for informing that the information or to the effect that the noise is generated 1 The flow rate measuring device described. The flow rate measuring device according to claim 1 or 2 , wherein the receiving means is in a state where it can always receive sound waves. When the signal output from the receiving unit is a signal corresponding to a flow rate equal to or higher than a predetermined flow rate, the noise determination control unit detects the signal as a sound wave having a frequency within a frequency band that may be noise, and the noise is detected. It determines with what has generate | occur | produced. The flow measuring device of Claim 3 characterized by the above-mentioned. If the noise determination control means further determines that the noise is generated, the noise determination control means increases the intensity of the output of the sound wave propagated from the transmitter to the fluid to be measured, and the flow rate or The flow rate measuring device according to any one of claims 1 to 4, wherein a signal / noise ratio in flow velocity measurement is increased. If a signal corresponding to a predetermined flow rate or flow velocity value or a temporal transition pattern of flow rate or flow velocity is output from the flow measurement means as being impossible in the predetermined use state as the flow measurement device, the signal either the flow rate measurement operation control means for controlling the operation of the flow rate measurement in the rate measuring device to perform the measurement of the flow rate or flow rate, ignoring one of claims 1 to 5, characterized in that it comprises further The flow rate measuring device according to one item. In place of the ignored signal, the flow rate measuring operation control means is a signal obtained by sampling prior to the sampling of the ignored signal and / or a signal obtained by sampling after the sampling of the ignored signal. The flow rate or flow velocity measurement operation in the flow rate measuring device is controlled so that the flow rate or the flow velocity is measured using the signal as a signal obtained at the sampling timing of the ignored signal. The flow rate measuring device according to claim 6 . The flow rate measurement operation control unit temporarily stores a signal output from the flow rate measurement unit over a predetermined number of sampling times, and uses the signal instead of the ignored signal to measure the flow rate or the flow velocity. The flow rate measuring device according to claim 6 or 7 , wherein the flow rate or flow rate measuring operation in the flow rate measuring device is controlled so as to perform. Wherein the fluid is a gas used as a fuel or energy source, which the flow rate measuring means for measuring the flow rate or integrated flow rate of the gas, which of the claims 1 to 8, characterized in that it functions as a gas meter The flow rate measuring device according to any one item. It has a transmitting means and a receiving means, and a sound wave is propagated from the transmitting means to the fluid to be measured and received by the receiving means, and at that time, the propagation time or propagation speed of the sound wave or the sing-around propagation period is measured. The noise in the flow rate measuring device having flow rate measuring means for measuring the flow rate or the flow rate of the fluid based on the propagation time or propagation speed of the sound wave or the sing-around propagation cycle. A control method for controlling determination,
A frequency within a frequency band that may cause noise when measuring the flow rate or flow velocity of the fluid by allowing the receiving means to receive a sound wave every predetermined period even during a non-sampling period in which the sampling is suspended. Is detected by the receiving means during the non-sampling period, and if a sound wave in the frequency band that can become the noise is repeatedly detected for a predetermined period and / or a predetermined number of times, noise is detected. If it is determined that the noise has occurred, and once the noise is detected, then the period in which the sound wave can be received for at least a predetermined time is set to be longer than the predetermined period before the noise is detected. A control method characterized by being shortened so that sound waves can be received frequently . The flow rate measuring device comprises an alarm means;
11. The control method according to claim 10 , wherein, when it is determined that noise is generated, the alarm means outputs information indicating that the noise is generated or an alarm for notifying the information. The control method according to claim 10 or 11 , wherein the receiving means is in a state in which sound waves can always be received. When the signal output from the receiving unit is a signal corresponding to a flow rate equal to or higher than a predetermined flow rate, the noise determination control unit detects the signal as a sound wave having a frequency within a frequency band that may be noise, and the noise is detected. The control method according to claim 12 , wherein it is determined that an error has occurred. If it is determined that the noise is generated, the signal / noise in the measurement of the flow rate or flow velocity is further increased by increasing the intensity of the sound wave propagating from the transmitter to the fluid to be measured. The control method according to claim 10 , wherein the ratio is increased. When a signal corresponding to a predetermined flow rate value or flow rate temporal transition pattern is output from the flow rate measuring means as being impossible in the predetermined use state, the signal is ignored. The flow measurement operation control means for controlling the flow measurement operation in the flow measurement device so as to measure the flow rate or the flow velocity is further provided. The method according to any one of claims 10 to 14 , further comprising: The control method described. Instead of the neglected signal, the signal obtained by sampling before the neglected signal sampling and / or the signal obtained by sampling after the neglected signal sampling are sampled by the neglected signal. The control method according to claim 15 , wherein the flow rate or flow velocity measurement operation in the flow rate measurement device is controlled so that the flow rate or flow velocity is measured using the signal obtained at the timing. The flow rate measurement unit is configured to temporarily store a signal output over a predetermined number of sampling times and use it instead of the neglected signal to measure the flow rate or the flow velocity. The control method according to claim 15 or 16 , wherein a measurement operation of a flow rate or a flow velocity in the apparatus is controlled. The fluid according to any one of claims 10 to 17 , wherein the fluid is a gas used as a fuel or an energy source, and the flow rate measuring means measures a flow rate or an integrated flow rate of the gas. The control method described.

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