JP2004085420A5 - - Google Patents

Description

[Document name] statement
Patent application title: Flow rate measuring deviceAnd flow rate measurement method
[Claim of claim]
  1. At least one pair of transducers provided in a fluid channel for sending and receiving ultrasonic signals, and sending and receiving of the transducersSwitch betweenSwitching means, an input unit for receiving the reception output of the transducer, reception detection means for detecting reception of an ultrasonic wave from the output of the input unit, andOn the sending sideDriving means for driving a vibrator, clocking means for measuring propagation time of ultrasonic waves between the vibrators, and counting of the clocking meansMeasurementFlow rate calculation means for calculating the flow rate based on the, OnA flow rate measuring device having an impedance control means for changing the impedance of a power unit.
  2. The impedance control means comprisesUltrasonicPropagation timeChange the input impedance according toThe flow rate measuring device according to claim 1.
  3. The impedance control means comprisesPropagation time of ultrasonic waveAs the input impedance of the input section becomes higher as it gets longerchangeThe flow rate measuring device according to claim 2.
  [Claim 4] At least a pair of transducers provided in a fluid channel for transmitting and receiving ultrasonic signals, switching means for switching transmission and reception of the transducers, an input unit for receiving the reception output of the transducers, and ultrasonic waves from the output of the input unit Reception detection means for detecting the reception of the wave, driving means for driving the transducer on the transmission side, clocking means for measuring the propagation time of the ultrasonic wave between the vibrators, and the flow rate based on the measurement value of the clocking means And a flow rate measuring method for calculating the flow rate by changing the input impedance according to the propagation time of the ultrasonic wave..
  5. The impedance control means comprisesChange input impedance according to flow rateThe flow rate measuring device according to claim 1.
  [6] The impedance control means changes the input impedance of the input section to increase as the flow rate increasesThe flow rate measuring device according to claim 5.
  [7] At least a pair of transducers provided in a fluid channel for transmitting and receiving ultrasonic signals, switching means for switching transmission and reception of the transducers, an input unit for receiving the reception output of the transducers, and ultrasonic waves from the output of the input unit Reception detection means for detecting the reception of the wave, driving means for driving the transducer on the transmission side, clocking means for measuring the propagation time of the ultrasonic wave between the vibrators, and the flow rate based on the measurement value of the clocking means And a flow rate measurement method for calculating the flow rate by changing the input impedance according to the flow rate..
  [Claim 8] Drive meansA drive timing detection means for detecting a timing of driving the vibrator;Detected by drive timing detection meansWhen driving a vibratorToInput impedance of input sectionchangeClaim to do1Flow rate measuring device as described.
  [9] OffSwitching timing detection means for detecting the timing at which the switching means operates, and the input impedance of the input section when the switching means operatesTheClaim to change1Flow rate measuring device as described.
  10. A power supply for supplying power to the control unit;Power supply timing detection means for detecting the timing at which the power supply operates, and after power onTime, Input impedance of input sectionChangeClaim1Flow rate measuring device as described.
Detailed Description of the Invention
      [0001]
  Field of the Invention
  The present invention relates to a flow rate measuring deviceAnd flow rate measurement methodIt is about
      [0002]
  [Prior Art]
  As shown in FIG. 4, a conventional flow rate measuring apparatus of this type is provided in the fluid channel 1 and is opposed to the first transducer 2 and the second transducer 3 for transmitting and receiving ultrasonic signals in the flow direction. The first vibrator 2 is driven by the driving means 4 to transmit an ultrasonic wave. The ultrasonic waves are received by the second transducer 3, and the reception detection means 5 determines the reception timing from the received signal. The clock means 6 measures the propagation time by measuring the time from when the drive means 4 drives the first vibrator 2 to when the reception detection means 5 determines the reception timing. Also, the direction of transmission / reception of the ultrasonic wave is changed by the switching means 7 to measure the propagation time of the ultrasonic wave in the reverse direction, and the flow rate is calculated by the flow rate calculating means 8 from the propagation time in both directions.
      [0003]
  [Problems to be solved by the invention]
  However, as in the equivalent circuit shown in FIG. 2, the equivalent circuit of the reception-side vibrator of the conventional flow rate measuring apparatus is a signal source 9 for converting ultrasonic vibration into an electric signal, an impedance 10 of the signal source 9, and a vibrator The signal output from the transducer is output as an electrical signal with a delay determined by the impedance 10 and the interelectrode capacitance 11 with respect to the vibration of the ultrasonic wave.
      [0004]
  In this case, if there is a temperature change, the value of the interelectrode capacitance 11 changes significantly, and the timing delay of the output signal changes, so accurate time measurement can not be performed. In order to make the variation of this delay small, there has been a method of receiving the output signal of the vibrator by a circuit whose impedance is lower than the internal impedance and shortening the delay time. However, the smaller the input impedance of the circuit receiving the output of the vibrator, the more current consumption is required, and since the output of the vibrator is received with a small impedance, the output signal of the vibrator becomes small and the output signal is detected for signal detection. The current consumption for amplification was increased. Therefore, there is a problem that the current consumption of the entire apparatus can be reduced without lowering the measurement accuracy.
      [0005]
  [Means for Solving the Problems]
  In order to solve the above problems, the present invention provides an impedance control means for changing the impedance of an input unit.Prepare.
      [0006]
  BEST MODE FOR CARRYING OUT THE INVENTION
  In the present inventionEmbodiment 1The flow rate measuring apparatus according to the present invention has impedance control means for changing the impedance of the input unit. And according to measurement conditions, it sets to input impedance which satisfies accuracy. This makes it possible to minimize the amplification factor necessary for signal detection from the output signal of the vibrator. As a result, since the setting can be made to satisfy the accuracy and reduce the current consumption, the current consumption can be reduced.
      [0007]
  In the present inventionEmbodiment 2The flow rate measuring device according toUltrasonicPropagation timeChange the input impedance according to. The preferred form is the propagation time of ultrasonic wavesAs the input impedance of the input section becomes higher as it gets longerchange. The error in flow measurement is a problem of the ratio of time measurement error to propagation time. Therefore, when the propagation time is long, the time measurement error also has a relatively large allowable value, and the measurement accuracy is improved more than necessary under the same reception condition.
      [0008]
  In this case, the electrical signal amplitude of the ultrasonic signal is increased by increasing the impedance of the input section within a range that satisfies the measurement accuracy. In addition, the S / N of the ultrasonic signal can be improved to reduce the variation of the measured value. In addition, since the amplitude of the input signal is increased, the degree of amplification of the signal can be reduced, so that the current consumption can be reduced.
      [0009]
  In the present inventionEmbodiment 3In the flow rate measuring apparatus according to the present invention, the impedance control means changes the input impedance of the input unit to be higher as the timekeeping by the timekeeping unit at the time of the previous measurement becomes longer. And, since the output of the clock unit is proportional to the propagation time, it is not necessary to measure the propagation time by using this value as the propagation time, and it is possible to reduce the power consumption for the propagation time measurement and to measure the measurement time It can be shortened.
      [0010]
  In the present inventionEmbodiment 4In the flow rate measuring apparatus according to the present invention, the impedance control means changes the measurement direction so that the input impedance of the input unit becomes higher as the sum of reciprocals of the outputs of the two time measuring units measuring the propagation time of ultrasonic waves increases. And since the propagation time which measured the propagation time which adjusted the flow velocity of the fluid to the sound speed of the fluid itself is measured, the propagation time measured is not the propagation time intrinsic to the fluid. Therefore, the propagation time from which the flow velocity of the fluid is removed can be determined by switching the measurement direction to obtain the reciprocal sum of the outputs of the two time measuring units, and setting the input impedance according to the propagation time more accurately. Can.
      [0011]
  In the present inventionEmbodimentThe flow rate measuring device for 5 isChange input impedance according to flow rate. The preferred form isChange the input impedance of the input section to be higher as the flow rate increases.Errors in flow measurement are in most cases based on the error ratio to the measured flow value. That is, when the time measurement error is constant, the measurement accuracy is improved more than necessary when the measurement flow rate is relatively large. In this case, by increasing the impedance of the input section, the electric signal amplitude of the ultrasonic signal is increased, so that the S / N of the ultrasonic signal can be improved and the variation of the measured value can be reduced.
      [0012]
  In the present inventionEmbodimentIn the flow rate measuring device according to 6, the flow rate detecting means receives the output of the flow rate calculating means in the flow rate detecting means and stores it.
      [0013]
  Since the input impedance of the input unit is controlled based on the value obtained by storing the output of the previous flow calculation means in the flow storage unit, it is not necessary to separately measure the flow, and power consumption for flow measurement can be reduced. , Measurement time can be shortened.
      [0014]
  In the present inventionEmbodimentThe flow rate detection means according to 7 includes prediction means for predicting the timing of receiving ultrasonic waves in the impedance control means, and changes the input impedance of the input part to a smaller value compared to the impedance of the vibrator only at the timing predicted by the prediction means. Do. Since the impedance of the input section is reduced only at the necessary timing for receiving the reception signal, the consumption current for reducing the impedance of the input section can be reduced, and at the same time, the input section does not receive the reception signal. Since the impedance of the sensor is high, the electrical loss is large, and the vibration generated in the vibrator can be attenuated quickly, so that it is possible to realize a flow measuring device with low current consumption and high accuracy.
      [0015]
  In the present inventionEmbodimentThe flow rate measuring deviceDrive meansA drive timing detection means for detecting a timing of driving the vibrator;Detected by drive timing detection meansWhen driving a vibratorToInput impedance of input sectionchangeDo.The preferred form isWhen driving the vibrator, the input impedance of the input unit is changed to a smaller value than the impedance of the vibrator. For this reason, even if noise or leakage signal caused by the drive signal for driving the transmission-side vibrator is generated to vibrate the reception-side vibrator, the input is compared with the case where the impedance of the input section is not low. Since a lot of energy flows also to the part, it becomes difficult for the receiving transducer to vibrate. As a result, it is possible to reduce the residual vibration remaining until the ultrasonic signal propagates to the reception side transducer and is received, so that it is possible to realize a highly accurate flow rate measuring device with low current consumption.
      [0016]
  In the present inventionEmbodimentThe flow rate measuring deviceSwitchSwitching timing detection means for detecting the timing at which the control means operates, and the input impedance of the input unitChangeDo.The preferred form isWhen the switching means operates, the input impedance of the input unit is changed to a smaller value than the impedance of the vibrator. For this reason, even if noise or leakage signals caused by the operation of the switching means are caused to vibrate the reception side vibrator, compared with the case where the input part is not made low impedance, even in the case of the input part. Because a large amount of energy flows, the receiving oscillator is less likely to vibrate. As a result, it is possible to reduce the residual vibration remaining until the ultrasonic signal propagates to the reception side transducer and is received, so that it is possible to realize a highly accurate flow rate measuring device with low current consumption.
      [0017]
  In the present inventionEmbodimentThe flow rate measuring device according to 10A power supply for supplying power to the control unit;Power supply timing detection means for detecting the timing at which the power supply operates, and after power onTime, Input impedance of input sectionChange.The preferred form isWhen the power is turned on, the input impedance of the input unit is set to a value substantially equal to the impedance of the vibrator. Even when the receiving-side vibrator vibrates when the power is turned on, energy can be most efficiently flowed to the input section, so that the vibration generated by the receiving-side vibrator can be reduced quickly, and the time until the flow rate measurement starts Can be shortened and current consumption can be realized.
      [0018]
  【Example】
  Hereinafter, embodiments of the present invention will be described with reference to the drawings.
      [0019]
  Example 1
  FIG. 1 is an overall block diagram showing a flow rate measuring apparatus according to a first embodiment of the present invention. FIG. 2 is an equivalent circuit of the vibrator of the present invention.
      [0020]
  In FIG. 1, reference numeral 1 denotes a fluid channel, through which a measurement fluid flows. Reference numerals 2 and 3 denote a first transducer and a second transducer, which transmit and receive ultrasonic signals. A driving unit 4 outputs a signal for driving the vibrator. An input unit 11 receives the output signals of the transducers 2 and 3 with low impedance. A switching unit 7 switches the connection between the transducers 2 and 3 and the driving unit 4 and the input unit 11. A reception detection means 5 detects a reception timing from the output signal of the input unit 12 and outputs it. 6 is a clocking means, which measures the time from when the start signal is input to when the output of the reception detecting means 5 is received. Reference numeral 8 denotes a flow rate calculating means, which obtains the flow rate from the output of the time counting means 6 by calculation. A propagation time detection unit 13 outputs the propagation time. Reference numeral 14 denotes a flow rate detecting means, which outputs the flow rate. An impedance control unit 15 changes the input impedance of the input unit 12 according to the output signal. A control unit 16 operates the switching unit 7 and outputs a start signal to the driving unit 4 and the timing unit 6 after switching setting of transmission and reception. Reference numeral 17 denotes reception timing detection means which detects the timing of driving of the drive means 4 and outputs the same to the impedance control means 15 after a time slightly shorter than the propagation time. Reference numeral 18 denotes drive timing detection means, which detects the drive means 4 from the control signal to the drive means 4 and outputs it to the impedance control means. A switching timing detection unit 19 detects switching timing from the control signal to the switching unit output by the control unit 16 and outputs the switching timing to the impedance control unit 15. A power supply timing detection means 20 detects that the power supply is turned on and outputs the power supply timing detection means 20 to the impedance control means 15.
      [0021]
  The operation will be described below. First, the control unit 16 controls the switching unit 7 in the direction to measure the propagation time. Here, since the propagation time from the first vibrator 2 to the second vibrator 3 is measured, the first vibrator 2 and the driving means 4 and the second vibrator 3 and the input unit 12 are respectively Connecting. Next, based on the outputs of the propagation time detection means 13 and the flow rate detection means 14, the impedance control means 15 makes the input impedance of the input part 12 high so that the input impedance of the input part 12 is high if the propagation time is long or the flow rate is high. Set Next, the control unit 16 outputs a start signal to the drive unit 4 and the clock unit 6, and the drive unit 4 outputs a signal for driving the first vibrator 2, and the clock unit 8 starts clocking. Ultrasonic waves are transmitted from the driven first transducer 2. Then, the reception signal received by the second vibrator 3 is received by the input unit 12, reception detection is performed by the reception detection unit 5, and the timing of the timing unit 6 is stopped. The clock means 6 outputs the clocked result to the arithmetic means 8.
      [0022]
  Next, the control unit 16 controls the switching means 7 to set the connection of the switching means 7 so as to measure the propagation time in the reverse direction. Thereafter, the measurement in the reverse direction is performed in the same manner, and the measurement result is output to the calculation means 8. The calculation means 8 obtains the flow rate by multiplying the reciprocal difference of the propagation time in both directions by a constant.
      [0023]
  As described above, in the present embodiment, the impedance control unit 15 sets the input impedance to satisfy the accuracy according to the measurement condition such as when the propagation time is long or the flow rate is large. This makes it possible to minimize the amplification factor necessary for signal detection from the output signal of the vibrator. As a result, since the setting can be made to satisfy the accuracy and reduce the current consumption, the current consumption can be reduced.
      [0024]
  Further, the impedance control means 15 is provided with a propagation time detection means 13 for detecting the propagation time, and the input impedance of the input section is changed to be high when the propagation time detected by the propagation time detection means 13 becomes long. The error in flow measurement is a problem of the ratio of time measurement error to propagation time. Therefore, when the propagation time is long, the time measurement error also has a relatively large allowable value, and the measurement accuracy is improved more than necessary under the same reception condition. In this case, the electrical signal amplitude of the ultrasonic signal is increased by increasing the impedance of the input section within a range that satisfies the measurement accuracy. In addition, the S / N of the ultrasonic signal can be improved to reduce the variation of the measured value. In addition, since the amplitude of the input signal is increased, the degree of amplification of the signal can be reduced, so that the current consumption can be reduced.
      [0025]
  Further, the impedance control means 15 is provided with the flow rate detection means 14 for detecting the flow rate, and the error in the flow rate measurement to change so that the input impedance of the input unit 12 becomes higher when the flow rate detected by the flow rate detection means 14 increases It is based on the error ratio to the measured flow value. That is, when the time measurement error is constant, the measurement accuracy is improved more than necessary when the measurement flow rate is relatively large. In this case, by increasing the impedance of the input section, the electric signal amplitude of the ultrasonic signal is increased, so that the S / N of the ultrasonic signal can be improved and the variation of the measured value can be reduced.
      [0026]
  Also, after receiving the start signal, the reception timing detection means 17 makes the impedance of the input part a small value by the output of the impedance control means 15 after a lapse of a time slightly shorter than the propagation time, so the reception signal needs to be received. Since the impedance of the input unit 12 is reduced only at the proper timing, the consumption current for reducing the impedance of the input unit 12 can be reduced, and at the same time the impedance of the input unit is high at the timing when the reception signal is not received. Therefore, since the electrical loss is large and the vibration generated in the vibrator can be quickly damped, it is possible to realize a flow measuring device with low current consumption and high accuracy.
      [0027]
  Further, the drive timing detection means 18 receives the start signal, detects the drive timing, and the output of the impedance control means 15 causes the timing at which the drive means 4 is operating to set the impedance of the input unit 12 to a small value. When driving a child, the input impedance of the input section is a smaller value than the impedance of the vibrator. For this reason, even if noise or leakage signal caused by the drive signal for driving the transmission-side vibrator is generated to vibrate the reception-side vibrator, the input is compared with the case where the impedance of the input section is not low. Since a lot of energy flows also to the part, it becomes difficult for the receiving transducer to vibrate. As a result, it is possible to reduce the residual vibration remaining until the ultrasonic signal propagates to the reception side transducer and is received, so that it is possible to realize a highly accurate flow rate measuring device with low current consumption.
      [0028]
  The switching timing detection unit 19 detects the operation of the switching unit 7 from the control signal from the control unit 16 to the switching unit 7, and the timing at which the switching unit 7 is operated by the output of the impedance control unit 15 is the impedance of the input unit Therefore, even if noise or leakage signals caused by the operation of the switching means 7 cause the receiving-side vibrator to vibrate, as compared with the case where the input section does not have low impedance, Since a large amount of energy flows also to the input unit, the receiving-side vibrator is less likely to vibrate. As a result, it is possible to reduce the residual vibration remaining until the ultrasonic signal propagates to the reception side transducer and is received, so that it is possible to realize a highly accurate flow rate measuring device with low current consumption.
      [0029]
  The power supply timing detection unit 20 sets the input impedance of the input unit 12 to substantially the same value as the impedance of the vibrator when the power is turned on. Even when the receiving-side vibrator vibrates when the power is turned on, energy can be most efficiently flowed to the input section, so that the vibration generated by the receiving-side vibrator can be reduced quickly, and the time until the flow rate measurement starts Can be shortened and current consumption can be realized.
      [0030]
  (Example 2)
  FIG. 3 is a block diagram showing the whole of the flow rate measuring apparatus according to the second embodiment of the present invention.
      [0031]
  The second embodiment differs from the first embodiment in that the impedance control means 15 receives the output of the timing means 6 instead of the propagation time detection means, and the flow rate detection means 14 outputs the output of the flow rate calculation means 8. This is a point to be stored and output to the impedance control means 15 at the next measurement, and the other blocks are the same as in the first embodiment, so the description will be omitted.
      [0032]
  The impedance control means 15 receives the output of the clock means 6, and changes the impedance of the input part 12 at the time of next measurement so that the input impedance of the input part 12 becomes high by the impedance control means 15 when the clocking by the clock part becomes long.
      [0033]
  By doing this, the impedance of the input unit 12 can be set to a value according to the propagation time without separately providing the propagation time detection means 13, and power consumption can be reduced.
      [0034]
  Further, the impedance control means 15 receives the outputs of the two time counting means 6 which switch the measurement direction and measure the propagation time of the ultrasonic wave. When the sum of reciprocals of the outputs of the two time counting means 6 is increased, the input impedance of the input unit 12 is changed to be higher.
      [0035]
  The measured propagation time is not the inherent propagation time of the fluid because the propagation time of ultrasonic waves is adjusted to the velocity of the fluid itself and the propagation time is measured. Therefore, the propagation time from which the flow velocity of the fluid is removed can be determined by switching the measurement direction to obtain the reciprocal sum of the outputs of the two clocking means 6, and the input unit 12 is set more accurately according to the propagation time. can do.
      [0036]
  Further, the flow rate detection means 14 stores the output of the previous flow rate calculation means 8, and the impedance control means 15 controls the input impedance of the input unit 12 based on the flow rate value stored in the flow rate detection means 14, There is no need to separately provide a flow rate detection means, power consumption for flow rate measurement can be reduced, and the measurement time can be shortened.
      [0037]
  【Effect of the invention】
  As described above, the flow rate measuring apparatus according to the present invention may be provided with impedance control means for changing the impedance of the input unit, and may be set to an input impedance that satisfies accuracy according to measurement conditions.it can.
Brief Description of the Drawings
  [Fig. 1]
  Block diagram of the flow rate measuring apparatus in the first embodiment of the present invention
  [Fig. 2]
  Equivalent circuit diagram of the vibrator part of the same flow rate measuring device
  [Fig. 3]
  Block diagram of the flow rate measuring apparatus in the second embodiment of the present invention
  [Fig. 4]
  Block diagram of conventional flow rate measuring device
  [Description of the code]
  1 Measuring pipeline
  2 1st oscillator
  3 Second oscillator
  4 Driving means
  5 Reception detection means
  6 Clock measures
  7 Switching means
  8 Flow rate calculation means
  12 Input section
  13 Means of detection of propagation time
  14 Flow rate detection means
  15 Impedance detection means
  17 Reception timing detection means
  18 Drive timing detection means
  19 Switching timing detection means
  20 Power supply timing detection means