JP2008275465A - Flow measuring apparatus, program of the same, flow measuring method, and fluid supply system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technique capable of highly accurately discriminating devices using a fluid by high-speed sampling while achieving low electric power consumption. <P>SOLUTION: In a gas meter 16, an ultrasonic flowmeter 7 transmits sampling signals at prescribed transmission intervals to measure the quantity of flow of gas flowing through a channel 6. A control part 22 controls the transmission intervals. A passive pressure-sensitive sensor 21 observes changes in the quantity of flow of gas different from the ultrasonic flowmeter 7 as pressure changes and issues a command signal to shorten the transmission intervals to the control part 22 in the case of capturing pressure changes. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a technique for correctly discriminating an instrument that uses a fluid by capturing a change in the flow rate of the fluid.

Conventionally, there is a system described in Patent Document 1 as a system for specifying a tool to be used in a fluid piping system having a flow rate measuring device. In this system, a predetermined detection unit that captures the start of use of the device captures a predetermined signal corresponding to an increase in the flow rate of the fluid. When this signal is received, flow rate sampling at a higher speed than the normal flow rate measurement that has been performed is started. In this way, the instrument is identified with high accuracy by performing high-speed measurement in accordance with the start of use of the instrument.
Japanese Patent Laid-Open No. 11-287684

  However, in the above configuration, only accuracy discrimination improvement is considered, and no consideration is given to power consumption. Since high-speed sampling increases power consumption, there are problems in terms of energy saving and improvement in usability of a flow rate measuring device using a battery to which no power is supplied from the outside.

  The present invention has been made to solve the above-described problems, and an object thereof is to provide a technique for accurately discriminating a device using a fluid while achieving low power consumption.

  The flow rate measurement device of the present invention includes a flow rate measurement unit that measures the flow rate of the fluid flowing in the flow path, a control unit that controls the transmission interval of the sampling signal for fluid flow rate measurement that is transmitted by the flow rate measurement unit, Separately from the flow rate measurement unit, the change in the flow rate is observed as a change in a predetermined physical quantity, and when the change in the physical quantity is captured, a passive command is issued to the control unit to shorten the transmission interval. A mold sensor.

  According to the invention, so-called passive sensors are used to capture changes in flow rate. Therefore, even in a flow rate measuring apparatus that performs so-called high-speed sampling, high-speed sampling can be performed when necessary, and low power consumption can be achieved.

  In the flow rate measuring device of the present invention, after the transmission interval is shortened, the control unit 1) when a predetermined time has elapsed, 2) when a predetermined number of times of sampling is completed, or 3) when the fluid flow rate is stabilized In addition, the transmission interval is lengthened.

  According to the above configuration, it is possible to save more power.

  Furthermore, in the flow rate measuring apparatus of the present invention, the control unit lengthens the transmission interval at the earlier timing when the predetermined time has elapsed after the transmission interval has been shortened and when the fluid flow rate has stabilized. .

  With the above configuration, it is possible to further save power.

  The said control part lengthens the said transmission interval, when the instrument which uses a fluid stops after shortening the said transmission interval.

  With the above configuration, it is possible to further save power.

  Moreover, in the said structure, when the said transmission interval is lengthened, you may make it return to the original interval before shortening the said transmission interval.

  When the physical quantity is a fluid pressure, the passive sensor can be constituted by a simple pressure-sensitive sensor. In addition, when the output of the command signal of the passive sensor is greater than or equal to a predetermined threshold, the control unit may shorten the sampling signal transmission interval.

  Furthermore, in the flow rate measuring apparatus of the present invention, a recording unit for recording the time when the passive sensor issues the command signal can be further provided. The recording unit may record the time when the control unit shortens the transmission interval.

  Furthermore, the present invention provides a flow measurement method executed by the flow measurement device and a computer for controlling the flow measurement device. Furthermore, a fluid supply system using these apparatuses, methods, and programs is provided.

  According to the present invention, low power consumption can be achieved even when high-speed sampling is used.

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

  FIG. 1 shows a block diagram of a gas meter as a flow rate measuring apparatus in an embodiment of the present invention.

  In FIG. 1, the gas meter 16 includes a flow path 6, an ultrasonic flowmeter 7 as a flow rate measurement unit, a measured flow rate information storage unit 8, an appliance discrimination unit 11, and an appliance-specific flow rate calculation unit 20. is there. Further, the gas meter 16 is disposed in the flow path 6 and includes a flow path cutoff valve 17 that shuts off gas in an emergency or the like, a pressure sensor 21, a control unit 22, and a recording unit 23.

  The ultrasonic flowmeter 7 measures the flow rate by emitting ultrasonic waves to a gas as a fluid flowing in the flow path 6, and a general one can be used. The measured flow rate information storage unit 8 stores the measured flow value measured by the ultrasonic flow meter 7 and target data described in association with the measured time when the measured flow rate value was measured.

  The appliance discriminating unit 11 discriminates a gas appliance that uses a fluid based on the above-described target data. Here, the appliance discriminating unit 11 compares the detected pattern of the target data with the flow rate pattern specific to the gas appliance stored in a memory (not shown) for each gas appliance in advance, and uses the gas from the correlation or the like. Identify the instrument.

  The flow rate calculation unit 20 for each appliance calculates the flow rate for each gas appliance determined by the device determination unit 11. Further, the gas meter 16 is connected to a gas pipe line 19 on the upstream side, and connected to various gas appliances 13, 14, 15 such as a gas table, a fan heater, and floor heating on the downstream side.

  FIG. 2 is an explanatory diagram of the ultrasonic flow meter 7 and the pressure sensor 21 disposed in the flow path 6. The flow path 6 has, for example, a rectangular cross section, and a pair of ultrasonic transmitters / receivers 7a and 7b is located upstream of the flow path with the flow path 6 sandwiched between walls perpendicular to the flow direction of the gas G1 in the flow path 6 And are mounted to face each other at an angle φ on the downstream side. Ultrasonic waves are alternately transmitted and received between the ultrasonic transmitters / receivers 7a and 7b, and the difference between the propagation times of the ultrasonic waves in the forward direction and the reverse direction with respect to the flow of the fluid is measured at regular intervals to generate a propagation time difference signal. . Based on this propagation time difference signal, the instantaneous gas flow rate is detected.

In FIG. 2, L is a measurement distance defined between the ultrasonic transmitters and receivers, where t1 is the transmission time from the upstream, t2 is the transmission time from the downstream, and C is the speed of sound, the flow velocity (flow rate) V is
(Expression 1) V = L / 2 cos φ ((1 / t1) − (1 / t2)).

  The above-mentioned flow rate measurement is performed, for example, by measuring an instantaneous flow rate at intervals of 2 seconds, that is, by sampling measurement. The gas flow rate measured by the ultrasonic flowmeter 7 is stored in the measured flow rate information storage unit 8 in a pattern of target data as shown in FIG. 3, for example, and the appliance discrimination unit 11 discriminates the gas appliance using the gas. To do. In general, the rising waveform at the time of starting the gas appliance shown in FIG. 3, the stable flow rate at the time of stable operation, etc. are observed, and by comparing the flow rate pattern specific to the gas appliance previously stored for each gas appliance, The determination unit 11 can determine the gas appliance to be used.

  However, in the sampling at intervals of 2 seconds, the flow rate data obtained is not precise, and the characteristics of the flow rate pattern that occurs in a short time of 2 seconds or less cannot be captured. In addition, it is difficult to discriminate between gas appliances that originally have similar flow patterns. In order to solve such a problem, in the present invention, as shown in FIG. 4, high-speed sampling is performed to shorten the sampling interval. According to the high-speed sampling, precise flow rate data can be obtained, so that the used gas appliance can be accurately identified.

  If such high-speed sampling is always performed, the number of times of measurement with the ultrasonic flowmeter 7 increases, and the power consumption of the ultrasonic flowmeter 7 increases. Therefore, it is a problem from the viewpoint of energy saving. Further, in the case of a gas meter driven by a battery, the number of batteries increases, which causes problems in terms of cost and size.

  Therefore, in the present invention, not only the concept of high-speed sampling described above but also a concept of performing high-speed sampling at an appropriate timing only when necessary is intended to save power. For example, high-speed sampling is started at a timing when a predetermined gas flow rate changes, such as at the time of slow ignition as shown in FIG. In order to perform such control, in the present embodiment, a change in the flow rate of the gas as a fluid is observed and detected by a pressure-sensitive sensor 21 that is a so-called passive sensor.

  The pressure-sensitive sensor 21 is constituted by a piezo element or the like, and generates a voltage based on a change in gas flow rate in the form of a pressure change based on the deflection or deformation of the element itself, and directly detects this voltage. Such a pressure-sensitive sensor 21 can use a commercially available sensor, and can be easily attached to the pipeline 6. In the example of FIG. 2, the pressure-sensitive sensor 21 is attached to the inner wall of the pipe 6 on the downstream side of the ultrasonic flowmeter 7, but the attachment location, the attachment mode, etc. are not particularly limited.

  A passive sensor typified by the pressure-sensitive sensor 21 is a sensor that observes a change in the gas flow rate as a change in a predetermined physical quantity (for example, pressure) separately from the ultrasonic flow meter 7. 7 is not an active sensor that actively transmits a sampling signal by itself. A passive sensor is triggered by a change in a predetermined physical quantity and emits a signal. Unlike an active sensor such as the ultrasonic flowmeter 7, the passive sensor does not always emit a sampling signal, Since it is activated for the first time when a change occurs, power consumption is small.

  When the pressure sensor 21 detects a change in the gas flow rate, the pressure sensor 21 issues a command signal to the control unit 22 to shorten the sampling signal transmission interval of the ultrasonic flowmeter 7. The control unit 22 serves to control the transmission interval of the sampling signal of the ultrasonic flow meter 7. The control unit 22 sets the normal transmission interval to about 2 seconds, but upon receiving the command signal, the control unit 22 sets a reduced transmission interval such as 1000 ms, 500 ms, and 200 ms, and becomes such a transmission interval. The ultrasonic flowmeter 7 is controlled.

  After shortening the transmission interval of the sampling signal as described above, the control unit 22 increases the interval again at a predetermined timing (usually returning to the original interval before the shortening). For example, after shortening the transmission interval, the control unit 22 increases (returns) the transmission interval when a predetermined time elapses or when a predetermined number of samplings are completed. Further, as represented by the stable flow rate in FIG. 3, the control unit 22 can increase the transmission interval when the gas flow rate is stabilized. By controlling in this way, it is possible to further save power consumption.

  Further, the control unit 22 may increase the transmission interval at the earlier timing when a predetermined time has elapsed after the transmission interval is shortened and when the gas flow rate is stabilized. Moreover, you may make it the control part 22 lengthen a transmission interval, when either of the gas appliances 13, 14, and 15 which use gas stops after shortening a transmission interval.

  Also, the control unit 22 may shorten the sampling signal transmission interval only when the output of the command signal of the pressure-sensitive sensor 21 is equal to or greater than a predetermined threshold.

  Furthermore, the gas meter 16 of the present embodiment is provided with a recording unit 23 that records a time substantially corresponding to the time at which high-speed sampling is started. The recording unit 23 records the time when the pressure-sensitive sensor 21 issues a command signal or the time when the control unit 22 shortens the transmission interval.

  As an example of the change in the gas flow rate at which high-speed sampling is started, it can be considered at the time of slow ignition or the start-up of the gas appliance as shown in FIG. 4, but also when the appliance is controlled. Since the characteristics of the control waveform can be grasped in detail, it is a target and is not particularly limited. If the flow rate is measured with normal sampling at such timing, a detailed flow rate waveform cannot be obtained, and accurate instrument discrimination may not be performed. For example, when the rising waveforms of the flow patterns of two gas appliances obtained in advance are similar, if the sampling interval of the rising waveforms is large, a minute change cannot be detected, and there is a possibility of discriminating between the two appliances. Therefore, by acquiring a detailed rising waveform by high-speed sampling, it is possible to accurately determine which flow pattern of the two gas appliances corresponds to.

  Incidentally, the slow ignition is a technique for suppressing abrupt ignition to a burner in a fan heater, a momentary water heater or the like and performing a gentle ignition (for example, Japanese Patent Laid-Open No. 5-99426). As shown in FIG. 4, the pressure-sensitive sensor 21 can detect a slow ignition by capturing a decrease in the increase rate of the flow rate or a decrease in the flow rate itself. Further, the pressure sensor 21 can detect the rising of the gas appliance when the flow rate increases even slightly from the zero flow rate.

  In order to carry out the flow rate measuring method as described above, the instrument discriminating unit 11 of the gas meter 16 and a computer (arithmetic unit) (not shown) store programs for executing the steps of the flow rate measuring method. In addition, a fluid supply system including a fluid (gas) supply source using a flow measurement device, a flow measurement method, and a program executed by a computer of the present invention is also included in the present invention.

  Although the above explanation has been given for the case where an ultrasonic flowmeter is used, it is obvious that the same effect can be obtained with other instantaneous flow measurement devices using a sampling signal. The processing after the device identification is omitted, but in the gas meter, the fee for each device by measuring the accumulated flow rate for each registered device or each classified group, and the safety management for each registered device or each classified group ( It is obvious that it is possible to set a security function for each device of the processing. In addition, if the gas meter and the gas appliance can be equipped with transmission / reception means such as a radio, it is clear that the accuracy of appliance discrimination is further improved. Furthermore, although the gas meter and the gas appliance have been described, the industrial flow meter and the water meter can also be used for specifying the appliances connected to the downstream side of the flow measuring device and for grouping the appliances.

  Although various embodiments of the present invention have been described above, the present invention is not limited to the matters shown in the above-described embodiments, and those skilled in the art can make modifications and applications based on the description and well-known techniques. This is also the scope of the present invention, and is included in the scope of seeking protection.

  As described above, according to the present invention, it is possible to achieve a device using a fluid with low power consumption even when high-speed sampling is used. While achieving energy saving, it is possible to improve the usability of a flow rate measuring device using a battery.

Block diagram of a gas meter in an embodiment of the present invention Figure near the ultrasonic flowmeter and pressure sensor in the gas meter pipeline The figure which shows the example of the flow change of the gas by use of the gas appliance Diagram showing an example of high-speed sampling

Explanation of symbols

7 Ultrasonic flow meter (flow rate measurement unit)
8 Measurement flow rate information storage unit 11 Appliance discriminating unit 13, 14, 15 Gas appliance 16 Gas meter (flow rate measuring device)
17 Channel shut-off valve 21 Pressure sensitive sensor 22 Control unit 23 Recording unit

Claims (14)

A flow rate measurement unit for measuring the flow rate of the fluid flowing in the flow path;
A control unit for controlling a transmission interval of a sampling signal for measuring a flow rate of a fluid transmitted by the flow rate measurement unit;
Separately from the flow rate measurement unit, the change in the flow rate is observed as a change in a predetermined physical quantity, and when the change in the physical quantity is captured, a passive command is issued to the control unit to shorten the transmission interval. Type sensors,
A flow rate measuring device comprising: The flow rate measuring device according to claim 1,
The control unit is a flow rate measurement device that lengthens the transmission interval when a predetermined time has elapsed after the transmission interval is shortened. The flow rate measuring device according to claim 1,
The control unit is a flow rate measuring device which lengthens the transmission interval when a predetermined number of samplings are completed after the transmission interval is shortened. The flow rate measuring device according to claim 1,
The said control part is a flow measuring device which lengthens the said transmission interval, when the flow volume of the fluid after shortening the said transmission interval is stabilized. The flow rate measuring device according to claim 1,
The control unit is a flow rate measuring device which lengthens the transmission interval at the earlier timing when a predetermined time elapses and when the fluid flow rate is stabilized after the transmission interval is shortened. The flow rate measuring device according to claim 1,
The said control part is a flow measuring device which lengthens the said transmission interval, when the instrument which uses a fluid stops after shortening the said transmission interval. The flow rate measuring device according to any one of claims 2 to 6,
When the said transmission part lengthens the said transmission interval, the said flow rate measuring apparatus which returns to the original space | interval before shortening the said transmission interval. The flow rate measuring device according to any one of claims 1 to 7,
The flow rate measuring device, wherein the physical quantity is a fluid pressure, and the passive sensor is a pressure-sensitive sensor. The flow rate measuring device according to any one of claims 1 to 8,
When the output of the command signal of the passive sensor is greater than or equal to a predetermined threshold, the control unit is a flow rate measurement device that shortens the sampling signal transmission interval. The flow rate measuring device according to any one of claims 1 to 9,
A flow rate measuring apparatus further comprising a recording unit that records a time at which the passive sensor issues the command signal. The flow rate measuring device according to any one of claims 1 to 9,
A flow rate measuring device further comprising a recording unit that records a time when the control unit shortens the transmission interval. Measuring the flow rate of the fluid flowing in the flow path;
Controlling the transmission interval of the sampling signal in the step of measuring the flow rate of the fluid;
Separately from the step of measuring the flow rate of the fluid, observing the change in the flow rate as a change in a predetermined physical quantity, and when capturing the change in the physical quantity, issuing a command signal to shorten the transmission interval;
A flow measurement method comprising: A program for controlling a flow measuring device to execute the following steps,
Measuring the flow rate of the fluid flowing in the flow path;
Controlling the transmission interval of the sampling signal in the step of measuring the flow rate of the fluid;
Separately from the step of measuring the flow rate of the fluid, observing the change in the flow rate as a change in a predetermined physical quantity, and when capturing the change in the physical quantity, issuing a command signal to shorten the transmission interval;
A program that causes a computer to execute.   A fluid supply system using the flow rate measuring device or the flow rate measuring method according to claim 1, or a program executed by a computer.

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