JP4485641B2 - Ultrasonic flow meter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an ultrasonic flow meter.
[0002]
[Prior art]
A pair of ultrasonic transducers that act as both transmitting and receiving sides are arranged at a certain distance from the upstream and downstream sides of the flow path, and the downstream transducers The forward propagation time of the ultrasonic wave when transmitting an ultrasonic pulse to the transducer, and the reverse propagation time of the ultrasonic wave when transmitting an ultrasonic pulse from the downstream transducer to the upstream transducer An ultrasonic flowmeter that measures the flow velocity of a fluid from the flow rate and further calculates the flow rate and uses the difference in propagation velocity between the forward direction and the reverse direction is well known.
[0003]
In this kind of ultrasonic flowmeter, the reception point that is received by the transmitter / receiver of the received wave from the time when the ultrasonic pulse is transmitted from the transmitter / receiver on the transmitting side to measure the propagation time (also called arrival time) The number of reference clocks up to is counted.
[0004]
In order to improve the measurement accuracy of the propagation time, the first transmission is performed first, the second transmission is performed at the same time as the reception, and the third transmission is performed at the same time as the reception. Thus, the transmission / reception was repeated a plurality of times, and the propagation time was measured for a plurality of times.
[0005]
By doing this, the measurement accuracy is improved several times compared to the case where the forward and reverse propagation times are each measured with only one transmission and reception, and the actual propagation time measurement resolution is increased several times. It was.
[0006]
[Problems to be solved by the invention]
By the way, in the flowmeter for liquids, since the speed of sound in the fluid is faster than that for gas, the propagation time of ultrasonic waves is shortened. Therefore, it is required to measure the propagation time with high resolution accordingly. Further, in order to constitute a flow meter in a small type, it is necessary to reduce the distance between the two ultrasonic transducers, since the propagation time is shortened because the, is also the propagation time measurement with high resolution requirements Is done.
[0007]
However, even if transmission of ultrasonic waves is instantaneous, it takes 100 μs or more to attenuate one received wave, so if the propagation time is 100 μs or less, the next ultrasonic pulse arrives before the received wave attenuates. and I got, which becomes noise, not possible to accurately identify the receiving point, can not improve the measurement accuracy by repeating a plurality of times of continuous reception of above, a small-type ultrasonic flow meter for liquid Was a major obstacle to the realization of.
[0008]
In addition, in order to measure a single propagation time with high resolution without repeated transmission and reception, a very high frequency reference clock in the order of GHz is required, which is technically, current-consuming and cost-effective. It was a problem.
[0009]
Accordingly, the present invention is to provide a very high without using a reference clock frequency, high measurement accuracy can be obtained, the ultrasonic flow meter small type it is possible to realize the ultrasonic flow meter for liquid Objective.
[0010]
[Means for Solving the Problems]
In order to achieve the above-mentioned object, the invention of claim 1 is provided with at least one pair of ultrasonic transducers acting on both the transmitting side and the receiving side, and each of the fluid flows in a forward direction and a reverse direction. An ultrasonic flowmeter that transmits and receives sound waves and obtains the flow rate and flow rate from the arrival time in each direction,
A reference clock oscillator for outputting a reference clock; and
A drive unit that drives the transmitter-side transmitter / receiver in synchronization with a reference clock a plurality of times (n times) at a fixed period in one measurement ;
A receiver that is connected to a transmitter / receiver on the receiving side and detects a reception point of the received wave;
A pulse output unit for outputting a first time pulse having a pulse length from the reception point to the immediately following clock synchronization point;
When a plurality of (n) first time pulses are sequentially input, a third pulse length having a total pulse length obtained by analogly adding the pulse lengths of the plurality (n) first time pulses is input. A pulse addition unit that outputs a time pulse;
The arrival time is obtained by subtracting the value measured by the reference clock from the sum of the times measured with the reference clock from the transmission drive performed several times to the clock synchronization point immediately after the reception point. This is an ultrasonic flowmeter characterized by the above.
[0014]
According to a second aspect of the present invention, in the ultrasonic flowmeter according to the first aspect , the pulse adding unit is constituted by an integrating circuit.
[0015]
The invention of claim 3 is provided with at least one pair of ultrasonic transducers acting on both the transmission side and the reception side, and transmits and receives ultrasonic waves in the forward and reverse directions in the fluid flow. An ultrasonic flowmeter that calculates the flow rate and flow rate from the arrival time in the direction,
A reference clock oscillator for outputting a reference clock; and
A drive unit that drives the transmitter-side transmitter / receiver in synchronization with a reference clock a plurality of times (n times) at a fixed period in one measurement;
A receiver that is connected to a transmitter / receiver on the receiving side and detects a reception point of the received wave;
A pulse output unit for outputting a first time pulse having a pulse length from the reception point to the immediately following clock synchronization point;
When a plurality of (n) first time pulses are sequentially input, the pulse lengths of the plurality (n) first time pulses are added in an analog manner, and the sum is multiplied (m times). A pulse addition / multiplication unit that outputs a fourth time pulse having a pulse length of
The pulse length of the fourth time pulse is reduced by 1 / m of the value measured with the reference clock from the sum of the times measured with the reference clock from the transmission drive performed several times (n times) to the synchronization point immediately after the reception point. Thus, the ultrasonic flowmeter is characterized in that one arrival time is obtained.
[0017]
According to a fourth aspect of the present invention, in the ultrasonic flowmeter according to the third aspect , the pulse addition / multiplication unit is configured by an integration circuit.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Next, preferred embodiments of the present invention will be described based on examples of the drawings.
[0019]
[Reference example]
Figure 1 shows the configuration of the reference example.
[0020]
The transducers 1 and 2 are ultrasonic transducers that can be used on both the transmission side and the reception side . In the state in which the change-over switches 3 and 4 are shown, the transducer 1 serves as a transmission side, and the transducer 2 serves as a reception side. Both transducers 1 and 2 transmit and receive ultrasonic waves in the fluid from upstream to downstream and from downstream to upstream.
[0021]
The receiving unit 5 outputs a received wave detection signal when a receiving side transducer (for example, 2) is connected and a receiving point is detected. The reception unit 5 detects a zero cross point between the third wave and the fourth wave of the reception wave as a reception point (see FIG. 2).
[0022]
When receiving the start signal from the control unit 7, the synchronization unit 6 outputs a transmission command signal to the drive unit 8 at the subsequent synchronization point with the reference clock (see FIG. 2).
[0023]
When the drive unit 8 receives the transmission command signal from the synchronization unit 6, the drive unit 8 drives the transmitter / receiver (for example, 1).
[0024]
The pulse output unit 9 outputs a first time pulse that becomes “High” by the received wave detection signal input from the receiving unit 5 and becomes “Low” at the first reference clock synchronization point thereafter (FIG. 2). The pulse length of this first time pulse is denoted by reference numeral T ₁ in FIG.
[0025]
The pulse multiplier 10 receives the first time pulse from the pulse output unit 9 and outputs a second time pulse having a pulse length mT _{1 obtained} by multiplying the time pulse length T ₁ by m while the time pulse becomes “Low”. (FIG. 2).
[0026]
The first counter 11 counts the time from the input of the transmission command signal from the synchronization unit 6 to the falling edge of the first time pulse from the pulse output unit 9 as the synchronization point of the reference clock from the reference clock oscillation unit 12 To measure. This value is output to the control unit 7.
[0027]
The first counter 11 is reset by a start signal from the control unit 7. The second counter 13 measures the pulse length of the second time pulse from the pulse multiplier 10 by counting the synchronization point of the reference clock. The control unit 7 reads the time (count value).
[0028]
The control unit 7 switches the roles of the two transducers 1 and 2 by inverting the transmission / reception switching signal at regular time intervals. After each switching, a start signal is output every time when noise or the like due to switching is suppressed. When all measurements are completed (detected by the second time pulse), the measured values (count values) of the first counter 11 and the second counter 13 are read, the forward arrival time is calculated, and the reverse performed immediately before Using the measured values in the direction, the flow rate and flow rate between them are calculated.
[0029]
In this reference example, the required resolution is to be ensured by one transmission in each of the forward and reverse directions. Since transmission is performed only once, reception is performed once, and therefore attenuation of reception is not related (the measurement interval is sufficiently larger than the attenuation time).
[0030]
In the prior art, the period of the reference clock is the resolution for arrival time measurement. However, in this reference example, the time T ₁ from the reception point to the immediately following reference clock synchronization point is analogally multiplied by m to mT _1, and by measuring it with the reference clock, the arrival time measurement resolution is m times. It is possible.
[0031]
If the reference clock period is T and the measurement result of the second time pulse is k,
Arrival time = T · (n′−k / m)
It becomes. Note that n ′ is a count value of the first counter 11 measured with the reference clock from the transmission driving time point to the reference clock synchronization point immediately after the reception point of the received wave as shown in FIG. 2, and the first value shown in FIG. This corresponds to the number of reference clock synchronization points at the falling point of the time pulse.
[0032]
In order to measure the arrival time with high accuracy, it is necessary to correctly set the size of m determined by the pulse multiplier 10 configured in an analog manner. It is possible to obtain accurate m by the time measured in reference clock definite time of one cycle of multiplying the reference clock and the results. Further, by periodically performing this measurement and correcting (calibrating) m, a change in temperature of the pulse multiplier 10 and the like can be allowed to some extent, so that expensive high-performance components do not need to be used .
[0033]
The pulse multiplication unit 10 in FIG. 1 can be configured by an integration circuit as shown in FIG . This circuit is configured by connecting an operational amplifier 14, a comparator 15, an OR gate 16, reference voltages -E and E, resistors R1 and R2, a capacitor C, a switch S1 that is closed by a first time pulse, and the like as illustrated. Yes.
[0034]
FIG. 3B is a signal waveform diagram showing the operation of the circuit of FIG. 3A. When the switches S1 and S2 are closed by the first time pulse, the output of the operational amplifier 14 rises by the integration operation.
[0035]
The conversion start signal is used by generating a signal that rises with a short WAIT from the falling edge of the first time pulse. When the switch S2 on the rising of the conversion start signal closes the output of the operational amplifier 14 is lowered by the product fraction operation, the comparator 15 defines the end of the second time pulse. The rise time of the second time pulse is determined by the rise of the conversion start signal. The pulse length of the second time pulse thus obtained is mT ₁ , where m is the circuit constants R1 and R2 of the integration circuit,
m = R1 / R2
It is determined as
[0036]
[Example 1 ]
In the above reference example , the flow rate / flow rate is measured once, and transmission / reception is performed once for each of the forward direction and the reverse direction. However, in Example 1 , the flow rate / flow rate is measured once. However, by performing transmission / reception a plurality of times (n times) at intervals greater than the time during which the received wave is reliably attenuated, the measurement accuracy is increased n times, and this corresponds to claim 1 .
[0037]
By making the interval between transmission and reception n times longer than the time required for attenuation of the received wave, the adverse effect of the previous received wave can be eliminated, and the portion below the clock period that cannot be counted with the reference clock is measured by adding n times in an analog manner. As a result, the measurement accuracy (substantial resolution) is improved n times.
[0038]
FIG. 4 is a waveform diagram for explaining the operation of this embodiment.
[0039]
When the pulse lengths of the first time pulse from the first time to the n-th time are t1, t2,..., Tn, the pulse length of the third time pulse is analog for each pulse length of the first time pulse. Of the value added to
Pulse length of third time pulse = t1 + t2 + ... + tn
Therefore, the pulse length is counted and measured using the reference pulse. And the sum of values Tl1, Tl2,..., Tln measured with the reference clock from the transmission driving performed several times (n times) to the clock synchronization point immediately after the reception point,
T (l1 + l2 + ... + ln)
The arrival time is obtained by subtracting the pulse length of the third time pulse from.
[0040]
That is, if the count value obtained by measuring the pulse length t1 + t ₂ +... + Tn of the third time pulse with the reference pulse is k, the arrival time is arrival time = T (l1 + l2 +... + Ln−k) / n, The measurement accuracy (resolution) of the flow velocity / flow rate obtained based on the arrival time is n times that in the reference example .
[0041]
FIG. 5 is a block diagram of the first embodiment. The transducers 1 and 2 are ultrasonic transducers that can be used on both the transmission side and the reception side. Both transducers 1 and 2 transmit and receive ultrasonic waves in the fluid from upstream to downstream and from downstream to upstream.
[0042]
The receiving unit 5 outputs a received wave detection signal when a receiving side transducer (for example, 2) is connected and a receiving point is detected.
[0043]
When the drive command unit 6A receives the start signal from the control unit 7A, the drive command unit 6A outputs a transmission command signal at a subsequent synchronization point with the reference clock, and thereafter outputs the transmission command signal every time a certain number of reference clocks are counted. This is repeated n times for one measurement.
[0044]
When receiving the transmission command signal from the drive command unit 6A, the drive unit 8 drives the transmitter / receiver (for example, 1).
[0045]
The pulse output unit 9 outputs a first time pulse which becomes “High” by the reception detection signal input from the receiving unit 5 and becomes “Low” at the first reference clock synchronization point thereafter.
[0046]
The pulse adder 17 receives the n first time pulses from the pulse output unit 9, the last (nth) first time pulse becomes “Low”, and the total pulse length of the first time pulse A third time pulse with a pulse length of is output.
[0047]
The first counter 11A synchronizes the reference clock from the reference clock oscillating unit 12 with the total time from the time when the oscillation command signal is input from the drive command unit 6A n times until the falling edge of the time pulse from the pulse output unit 9. The point is measured by counting with the first counter 11A. This value is output to the control unit 7A.
[0048]
The first counter 11A is reset by a start signal from the control unit 7A. The second counter 13A measures the pulse length of the third time pulse from the pulse adder 17 by counting the synchronization point of the reference clock. The time (count value) is read by the control unit 7A.
[0049]
The controller 7A switches the roles of the two transducers 1 and 2 by inverting the transmission / reception switching signal at regular time intervals. After each switching, a start signal is output every time when noise or the like due to switching is suppressed. When all measurements are completed (detected by the third time pulse), the measurement values (count values) of the first counter 11A and the second counter 13A are read, the arrival time is calculated, and this arrival time and its Using the measured value of the arrival time in the reverse direction performed immediately before, the flow velocity and flow rate between them are calculated.
[0050]
In the first embodiment, the pulse adding unit 17 can be configured by an integrating circuit (claim 2 ). FIG. 6A is a circuit diagram of this integration circuit, which has substantially the same configuration as the integration circuit of FIG. 3A in the reference example , but has only one integration resistor R. FIG. 4B shows the operation. When n first time pulses are inputted at a constant time interval, the switch S1 is turned on each time and the output of the operational amplifier 14 constituting the integrating circuit becomes the integration constant. RxC rises.
[0051]
The conversion start signal is used to create a credit that rises after a short WAIT from the falling edge of the nth first time pulse. The output of the operational amplifier 14 starts from the rising edge of the conversion start signal and falls at the integration constant R × C. The zero point is detected by the comparator 15 to determine the end point of the third time pulse.
[0052]
[Example 2 ]
The second embodiment corresponds to claim 3 and its block diagram is shown in FIG. This block diagram is significantly different from the block diagram of FIG. 5 in that a pulse addition / multiplication unit 18 is used instead of the pulse addition unit 17.
[0053]
The transducers 1 and 2 are ultrasonic transducers that can be used on both the transmission side and the reception side. Both transducers 1 and 2 transmit and receive ultrasonic waves in the fluid from upstream to downstream and from downstream to upstream.
[0054]
The receiving unit 5 outputs a received wave detection signal when a receiving side transducer (for example, 2) is connected and a receiving point is detected.
[0055]
When the drive command unit 6A receives the start signal from the control unit 7B, the drive command unit 6A outputs a transmission command signal at the subsequent synchronization point with the reference clock, and thereafter outputs the transmission command signal every time a certain number of reference clocks are counted. This is repeated n times for one measurement.
[0056]
When receiving the transmission command signal from the drive command unit 6A, the drive unit 8 drives the transmitter / receiver (for example, 1).
[0057]
The pulse output unit 9 outputs a first time pulse which becomes “High” by the reception detection signal input from the receiving unit 5 and becomes “Low” at the first reference clock synchronization point thereafter.
[0058]
The pulse addition / multiplication unit 18 inputs the n first time pulses from the pulse output unit 9, and adds the pulse lengths of the n first time pulses in an analog manner (the thus obtained FIG. 4 in FIG. 4). After obtaining the same pulse length as the third time pulse having a pulse length of t1 + t2 +... + Tn), a fourth time pulse having a pulse length obtained by multiplying the sum by m times is output. The fourth time pulse is output when the nth first time pulse becomes “Low”.
[0059]
The first counter 11A calculates the sum of the time from the time when the oscillation command signal is input n times from the drive command unit to the falling edge of the time pulse from the pulse output unit 9 to the synchronization point of the reference clock from the reference clock oscillation unit 12 Measure by counting. This value is output to the control unit 7B.
[0060]
The first counter 11A is reset by a start signal from the control unit 7B. The second counter 13A measures the pulse length of the fourth time pulse from the pulse addition / multiplication unit 18 by counting the synchronization point of the reference clock. The time (count value) is read by the control unit 7B.
[0061]
The controller 7B switches the roles of the two transducers by inverting the transmission / reception switching signal at regular intervals.
[0062]
After each switching, a start signal is output every time when noise or the like due to switching is suppressed. When all measurements are completed (detected by the fourth time pulse), the measurement values (count values) of the first counter 11A and the second counter 13A are read, the arrival time is calculated, and this arrival time and immediately before it are calculated. Using the measured value in the reverse direction performed in step 1, the flow velocity and flow rate are calculated.
[0063]
In the second embodiment, in order to monitor the accurate value of m of the pulse addition / multiplication unit 18, apart from the normal measurement, one period of the reference clock or an integer multiple thereof is periodically set as the pulse length. The multiplication value (m) can be corrected (calibrated) by inputting one or a plurality of pulses to the pulse addition / multiplication unit 18 and measuring the multiplied (m times) pulse length with a reference clock . In this way, the temperature change of the pulse addition / multiplication unit 18 can be allowed to some extent, and the measurement accuracy can be improved without using expensive high-performance components.
[0064]
FIG. 8 shows an embodiment of a circuit in which the pulse addition / multiplication unit 18 shown in FIG. 7 is constituted by an integration circuit. FIG. 8A is a circuit diagram, and FIG. The hardware configuration of the circuit is similar to that shown in FIG. 3A, and the action thereof is the addition operation of the pulse lengths of the n first time pulses described in FIG. 6B and FIG. The operation is the same as that of the multiplication operation for multiplying the pulse length described in (1) to m times.
[0065]
【The invention's effect】
Since the ultrasonic flowmeter according to the present invention is configured as described above, the flow velocity / flow rate is determined based on the arrival time measured by the prior art based on the value quantized with the reference clock, which cannot be avoided. A high-accuracy ultrasonic flowmeter can be realized by breaking through the resolution wall of one cycle of the reference clock. Also, since one cycle following measurement accuracy of the reference clock is obtained, without increasing the frequency of the reference clock, the small type ultrasonic flow meter for light liquid reaching time (propagation time) can be achieved.
[0067]
Also, by increasing the number of repeated transmissions / receptions, the accuracy increases, for example, n times.
[0068]
In any invention, high measurement accuracy can be obtained without increasing the frequency of the reference clock. Conversely, by reducing the frequency of the reference clock to reduce current consumption, a battery-driven ultrasonic flowmeter can be realized. There are also benefits to contribute.
[Brief description of the drawings]
FIG. 1 is a block diagram of a reference example of the present invention.
FIG. 2 is a signal waveform diagram for explaining the operation of the reference example of FIG.
3 is a specific example of a pulse multiplier used in the reference example of FIG. 1. FIG. 3A is an electric circuit diagram, and FIG. 3B is a signal waveform diagram for explaining the operation.
FIG. 4 is a signal waveform diagram illustrating the operation of the first embodiment of the present invention.
FIG. 5 is a block diagram of Embodiment 1 of the present invention.
6A and 6B are specific examples of the pulse adder used in the embodiment of FIG. 5, in which FIG. 6A is an electric circuit diagram, and FIG. 6B is a signal waveform diagram for explaining the operation.
FIG. 7 is a block diagram of Embodiment 2 of the present invention.
8A and 8B are specific examples of the pulse addition / multiplication unit used in the embodiment of FIG. 7, in which FIG. 8A is an electric circuit diagram, and FIG. 8B is a signal waveform diagram for explaining the operation.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1, 2 Ultrasonic transmitter / receiver 3, 4 Changeover switch 5 Receiving part 6 Synchronization part 6A Drive command part 7, 7A, 7B Control part 8 Drive part 9 Pulse output part 10 Pulse multiplication part 11, 11A 1st counter 12 Reference | standard Clock oscillator 13, 13A Second counter 14 Operational amplifier 15 Comparator 16 OR gate 17 Pulse adder 18 Pulse addition multiplier

Claims (4)

Provide at least one pair of ultrasonic transducers acting on both the transmitting side and the receiving side, and transmit and receive ultrasonic waves in the fluid flow in the forward and reverse directions respectively. An ultrasonic flow meter for determining a flow rate,
A reference clock oscillator for outputting a reference clock; and
A drive unit that drives the transmitter-side transmitter / receiver in synchronization with a reference clock a plurality of times (n times) at a fixed period in one measurement;
A receiver that is connected to a transmitter / receiver on the receiving side and detects a reception point of the received wave;
A pulse output unit for outputting a first time pulse having a pulse length from the reception point to the immediately following clock synchronization point;
When a plurality of (n) first time pulses are sequentially input, a third pulse length having a total pulse length obtained by analogly adding the pulse lengths of the plurality (n) first time pulses is input. A pulse addition unit that outputs a time pulse;
The arrival time is obtained by subtracting the value measured by the reference clock from the sum of the times measured with the reference clock from the transmission drive performed several times to the clock synchronization point immediately after the reception point. Ultrasonic flowmeter characterized by that. Ultrasonic flowmeter according to claim 1, wherein the pulse adding section configured in the integrating circuit. Provide at least one pair of ultrasonic transducers acting on both the transmitting side and the receiving side, and transmit and receive ultrasonic waves in the fluid flow in the forward and reverse directions respectively. An ultrasonic flow meter for determining a flow rate,
A reference clock oscillator for outputting a reference clock; and
A drive unit that drives the transmitter-side transmitter / receiver in synchronization with a reference clock a plurality of times (n times) at a fixed period in one measurement;
A receiver that is connected to a transmitter / receiver on the receiving side and detects a reception point of the received wave;
A pulse output unit for outputting a first time pulse having a pulse length from the reception point to the immediately following clock synchronization point;
When a plurality of (n) first time pulses are sequentially input, the pulse lengths of the plurality (n) first time pulses are added in an analog manner, and the sum is multiplied (m times). A pulse addition / multiplication unit that outputs a fourth time pulse having a pulse length of
The pulse length of the fourth time pulse is reduced by 1 / m of the value measured with the reference clock from the sum of the times measured with the reference clock from the transmission drive performed several times (n times) to the synchronization point immediately after the reception point. An ultrasonic flowmeter characterized in that one arrival time is obtained. 4. The ultrasonic flowmeter according to claim 3, wherein the pulse addition / multiplication unit is constituted by an integration circuit.

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