JPS6122771B2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a flow rate correction device in a flowmeter,
This method attempts to measure the flow rate of a fluid whose volume changes depending on physical quantities such as pressure and temperature as the flow rate at a certain reference pressure or reference temperature.

Generally, when measuring compressible fluids, the volume of the fluid changes depending on pressure and temperature, making the measurement results virtually meaningless, regardless of whether a positive displacement flowmeter or a vane-type flowmeter is used. . Therefore, in the present application, physical quantities such as pressure and temperature of the fluid to be measured are detected, and the flow rate of the fluid can be corrected to the flow rate at a certain reference value based on the detected values.

Hereinafter, the present application will be explained with reference to the drawings. Reference numeral 1 denotes a pipe for measuring the flow rate of a fluid to be measured, and the pipe 1 includes a flow meter 2 such as a roots meter or a turbine meter for measuring the flow rate, and a physical quantity of the fluid to be measured. A pressure sensor 3 is provided for detecting the fluid pressure. Reference numeral 4 denotes a flow rate transmitter which is connected to the flow meter 2 and is constructed of a high frequency transmitting type or a reed switch type, and converts the measured value of the flow meter 2 into a pulse signal as a flow rate pulse.

Reference numeral 5 denotes a flow rate correction device which is a main part of the present application, and will be explained below.The flow rate of the compressible fluid has the following relationship. That is, taking pressure as an example of the physical quantity of the fluid to be measured, Q ₀ = Q ₁ {1 + (P - P ₀ ) α} Here, P ₀ : A certain reference pressure P : Fluid pressure at the time of measurement Q ₀ : Flow rate at a reference pressure Q ₁ : Flow rate at a certain pressure P α : There is a relationship between the volume change rate due to pressure change of the measured fluid. As can be seen from the equation, by multiplying the flow rate Q ₁ by the correction coefficient, the flow rate Q ₁ can be corrected to the flow rate Q ₀ at the reference pressure P ₀ . Note that the above formula uses pressure as an example of a physical quantity, but if temperature is used as an example of a physical quantity, then "a certain reference pressure" and "fluid pressure at the time of measurement" in the above equation will become "a certain reference temperature" and "measuring fluid pressure", respectively. The temperature of the fluid at In the following explanation, pressure will be used as an example of a physical quantity.

The flow rate correction device 5 embodies the above formula, and the flow rate pulse from the flow rate transmitter 4 is passed through the frequency divider 6.
The signal is frequency-divided by and output to an analog-to-digital converter 8 (hereinafter referred to as A/D converter 8) via a delay circuit 7. The A/D converter 8 converts pressure as a physical quantity detected by the pressure sensor 3 into a predetermined pulse signal. The output of the A/D converter 8 is output to a memory type frequency divider 9, where it is converted into a predetermined pulse signal, and the pulse signal remaining after frequency division is held in the memory type frequency divider 9. Memory type frequency divider 9
The output pulses are input to a counter device indicated by reference numeral 14. To briefly explain the counter device 14, the counter device 14 counts the pulse signal in a reset state upon input of the pulse signal from the memory type frequency divider 9, and when the counted value is smaller than a certain value, the counter device 14 counts the pulse signal as described below. A gate close signal is output to the gate 17 (described later), and the count value is output as a count signal to the multiplier 12 (described later), and when the count value is above a certain value, a gate open signal is output to the gate 17 and the count value is calculated from the count value. A value obtained by subtracting a certain value is output to the multiplier 12 as a count signal. Next, the counter device 1
4, the counter device 14 is composed of a counter 10, a memory 11, a flip-flop 15, and a memory 16. Each of these devices is connected as follows. That is, the pulse signal of the memory frequency divider 9 is input to the counter 10. Here, the counter 10 is used, for example, to determine a constant value for obtaining the opening/closing signal of the gate 17.
A 1-digit decimal counter is used (the constant value is "10"), which counts the pulse signal from the memory type frequency divider 9, and outputs the counted value as a BCD output to the memory 11 as a counted signal. Output or subtract a certain value to memory 1 as a count signal.
1, and in conjunction with the output of the count signal to the memory 11, a gate opening/closing signal of the gate 17 is output to the flip-flop 15.

When the count signal is output from the counter 10, the signal is temporarily stored in the memory 11, and the count signal stored in the memory 11 is output to the multiplier 12. Every time the multiplier 12 receives a count signal as a BCD signal, it outputs a number of pulse signals corresponding to the count signal to an adder 13, which will be described later. Also,
When the pulse signal from the memorized frequency divider 9 is less than "10", the counter 10 outputs a flip-flop 15.
"0" is output as a gate close signal to the set terminal of the flip-flop 15, and "1" is output as a gate open signal to the set terminal of the flip-flop 15 when the pulse signal from the memory type frequency divider 9 is "10" or more. Output. A signal of "0" or "1" from the flip-flop 15 is output to the memory 16 and stored in the memory 16, and even if the flip-flop 15 is reset, that signal remains at the gate 17 until a new signal arrives from the flip-flop 15 to the memory 16. It is held as an opening/closing signal.

R is a reset signal, and the output signal of the frequency divider 6 is used to reset the counter 10 and the flip-flop 15. It is also output to the D converter 8. The reason for this is that the counter 10 and flip-flop 15 are reset before the A/D converter 8 outputs a pulse signal corresponding to the pressure signal from the pressure sensor 3 to the counter 10. T is a transition signal, and the output signal of the frequency divider 6 is used as the transition signal T, and as described above, the count signal stored in the memory 11 is outputted to the multiplier 12 by the transition signal T. The gate opening/closing signal for the gate 17 stored in the memory 16 is outputted to the gate 17. As a result, the gate 17 is "open" or "closed"
is controlled to the state of

On the other hand, the flow rate pulse from the flow rate transmitter 4 is input to the multiplier 12 via the delay circuit 18, and the multiplier 12 is, for example, input to the flow rate transmitter 4.
It is configured to output a number of count signals corresponding to the BCD signal previously output from the memory 11 to the adder 13 every time 10 flow pulses arrive. Furthermore, since the flow rate pulse from the flow rate transmitter 4 is input to the adder 13 via the delay circuit 19 and the gate 17, only when the gate 17 is in the "open" state, the pulse signal of the multiplier 12 and the flow rate The flow rate pulse of the transmitter 4 is added.

Next, to explain the operation of the present invention having the above structure, it is assumed that the correction coefficients of the fluid to be measured have the relationship shown in FIG. 2 in order to embody the above equation. That is, the reference pressure P ₀ is set to 3 [Kg/cm ² ].

Here, the A/D converter 8 has a reference pressure of 3 [Kg/
cm ² ], set it to output 2000 [pulses], and for other pressure conditions, set it to generate a pulse signal by multiplying 2000 [pulses] by the correction coefficient shown in Figure 2. .

First, the case where the measured fluid has a reference pressure P ₀ will be explained.

At the same time as the power (not shown) is turned on, an initial setting signal equivalent to the output of the frequency divider 6 is generated, and the pressure at that time (3 [Kg/cm ² ]) is converted into 2000 [pulses] by the A/D converter 8. The signal is converted into a pulse signal and input to the memory type frequency divider 9. The storage type frequency divider 9 consists of two 1/10 frequency dividers and one 1/2 frequency divider. Therefore, a pulse signal of 2000 [pulses] becomes 10 pulse signals and is sent to the counter 10. Since the counter 10 is a 1-digit decimal, it outputs a signal of "1" to the flip-flop 15,
The BCD output to the memory 11 becomes "0000". That is, since the aforementioned count value is "10" and the constant value is also "10,""1" is sent to the flip-flop 15 as a gate open signal, and this "1" signal is output to the memory 16 and stored in the memory. 16 and the BCD of the flip-flop 15
The output is output to the memory 11 and held in the memory 11.

Here, when a metering start button (not shown) is pressed, a flow rate pulse is output from the flow rate transmitter 4. At this first flow rate pulse, the frequency divider 6 sends the memory 11
The transition signal T is applied to 16 and 16, and the BCD output of the multiplier 12 connected to the memory 11 becomes "0000", and the gate 17 becomes "open". On the other hand, a reset signal R is sent from the frequency divider 6 to the counter 10 and the flip-flop 15, and a flow rate pulse is sent to the A/D converter 8 via the delay circuit 7, and the pressure at that point is sent to the A/D converter. A/D conversion is performed at 8 (pressure remains unchanged at 3
[Kg/cm ² ], so 2000 [pulses] are output again), and the contents of the counter 10 and flip-flop 15 are updated to the same contents as last time.
Now, the 10 pulse signals output from the flow rate transmitter 4 are passed through the delay circuit 18 to the multiplier 12.
added to. BCD of this multiplier 12
Since the input is "0000" as described above, the output is "0". Further, the pulse signal from the flow rate transmitter 4 is applied to the gate 17 through a delay circuit 19. Since this gate 17 is "open" as described above, the 10 flow rate pulses are directly added to the adder 13 as outputs. That is, the adder 13 adds the flow rate pulse input from the flow rate transmitter 4 and the output from the multiplier 12, resulting in counting 10 pulses, which are the same as the flow rate pulses of the flow rate transmitter 4. The frequency divider 6 outputs an actuation signal, a transition signal T, and a reset signal R every 10 flow pulses from the flow rate transmitter 4, so the 11th and 21st pulses, including the first pulse, are generated. ,...The same operation as the first one is repeated every 10 flow pulses. Therefore, every 10 flow rate pulses from the flow rate transmitter 4 are A/D converted and counted by the adder 13 for 10 pulses as long as the pressure is in the reference state.

This means that the flow rate pulses of the flow rate transmitter 4 and the number of pulses of the flow rate correction device 5 are equal, and the case where the correction coefficient is "1" is realized.

Next, a case where the pressure is 2 [Kg/cm ² ] will be explained as an example.

A pulse signal of 1500 pulses is applied from the A/D converter 8 to a memory type frequency divider 9. The number of pulse signals sent from the memory frequency divider 9 to the counter 10 is seven, and since the output from the counter 10 to the flip-flop 15 is "0", the gate 17 is in the "closed" state. Therefore, the BCD output of counter 10 to multiplier 12 is "0111" and the output of flip-flop 1 to gate 17 is "0111".
The output from 5 is "0". Thus, the next 10 flow rate pulses from the flow rate transmitter 4 are 7 from the multiplier 12 and 0 from the gate 17, so the added value of the adder 13 is 7. On the other hand, during the period when 10 pulses are being sent from the flow rate transmitter 4 as input for these 7 pulses, the A/D converter 8 performs the next conversion and again stores the 1500 [pulses] pulse signal into memory form. It is given to the frequency generator 9. At this time, the output from the memory frequency divider 9 to the counter 10 is the remaining 100 [pulses] from the previous time and the current 1500 [pulses].
There are eight pulses corresponding to a total of 1600 [pulses], and since the constant value "10" is not reached, the output to the flip-flop 15 is "0". Thus adder 1
The addition value of 3 is 8 for 10 flow pulses from the flow transmitter 4. Therefore, while the number of flow rate pulses from the flow rate transmitter 4 is 20 in total, the added value of the flow rate correction device is 15 in total, resulting in a correction of 0.75 times.

Then, if the fluid pressure is greater than the reference pressure P ₀ ,
That is, for example, the case of 4 [Kg/cm ² ] will be explained.

2500 pulse signals are applied from the A/D converter 8 to a memory type frequency divider 9. The number of pulse signals sent from this memory type frequency divider 9 to the counter 10 is 12, and since this value is greater than the above-mentioned constant value "10",
The output sent from counter 10 to flip-flop 15 is "1". Therefore, the BCD output of the counter 10 to the multiplier 12 is “0010”
The output from flip-flop 15 to gate 17 is "1". Thus, the next 10 flow pulses from the flow transmitter 4 are given to the adder 13 as two by the multiplier 12, and 10 flow pulses are given to the adder 13 from the gate 17. The added value will be 12. For the subsequent 10 flow rate pulses from the flow rate transmitter 4, use the same method as described above to calculate the total of 100 [pulses] remaining in the memorized frequency divider 9 and the new 2500 [pulses] for 2600 [pulses]. Pulse signal “13” is the counter 10
Since the output to the flip-flop 15 is "1", the added value of the adder 13 is 13 for the 10 flow pulses from the flow transmitter 4. In this way, the ratio is 25 out of 20 in total, and the correction is 1.25 times.

As described above, the flow rate pulse 10 from the flow rate transmitter 4 is
A/D convert the pressure value for each item and set the correction value,
In the procedure of sequentially correcting the set value at the time of 10 subsequent flow rate pulses from the flow meter, the correction value is never rounded down and is added up one after another for each setting.

Note that this embodiment embodies a flow rate correction device with an accuracy of 0.05% as a target, but this can be achieved by increasing the accuracy of the A/D converter 8 and increasing the number of digits of the memorized frequency divider 9. Accuracy can be increased to 0.01% or 0.005%, etc.

Further, in this embodiment, it is assumed that α in the equation, that is, the volume change rate of the fluid to be measured is constant, but it is generally not constant, and in that case, the A/D converter 8 is a nonlinear converter. You can use

Furthermore, the flow rate pulse from the flow rate transmitter 4 is output to the A/D converter 8 via the frequency divider 6, but this is possible, for example, by having the flow rate transmitter 4 emit two types of pulses. Other configurations may be used, such as outputting one pulse number at a predetermined ratio to the other pulse number and inputting this output to the A/D converter 8.

Furthermore, although the above embodiments have been described using pressure as an example of a physical quantity, as described above, this physical quantity may also be temperature.

The present invention is constructed as described above and has the following advantages.

Since the memory type frequency divider is used to calculate the pulse signal of the A/D converter without cutting it off, it is possible to perform flow rate measurement with extremely high measurement density. Further, in relation to the conversion accuracy of the A/D converter, it is possible to realize a flow rate correction device that has extremely high accuracy and can easily change the accuracy by simply changing the number of digits of the memory type frequency divider. Furthermore, since the configuration is such that correction is performed each time the flow rate pulse from the flow rate transmitter reaches a predetermined number of pulses, the speed and fidelity of flow rate measurement are greatly improved.

[Brief explanation of the drawing]

Figure 1 is a schematic system diagram of the present flow rate correction device, Figure 2
The figure is an example showing the relationship between the pressure of the measured fluid and the correction coefficient, which is measured using the flow rate correction device of the present application, taking pressure as an example of a physical quantity. 1...Piping, 2...Flowmeter, 3...Pressure sensor, 4...
Flow rate transmitter, 5...Flow rate correction device, 6...Frequency divider,
7, 18, 19...delay circuit, 8...A/D converter,
9... Memory type frequency divider, 10... Counter, 11, 16
...Memory, 12...Multiplier, 13...Adder, 14...Flow rate correction device, 15...Flip-flop, 17...Gate.

Claims (1)

[Claims] 1. A flow rate transmitter that outputs a flow rate pulse corresponding to the flow rate of the fluid to be measured, which is driven every predetermined number of flow rate pulses from the flow rate transmitter, and stores a predetermined number of pulse signals corresponding to the physical quantity of the fluid to be measured. an analog-digital converter that outputs the pulse signal from the analog-to-digital converter, a memory-type frequency divider that divides the frequency of the pulse signal from the analog-to-digital converter and outputs it to the counter device, The pulse signal is counted while being reset at the time of input, and when the counted value is smaller than a certain value, a gate close signal is output to the gate, and the counted value is output to the multiplier as a counting signal, and when the counted value is greater than a certain value a counter device which outputs a gate open signal to the gate and outputs a value obtained by subtracting the constant value from the count value to the multiplier as a count signal; a multiplier that converts it into a pulse signal and outputs it to an adder; and a multiplier that opens based on the gate open signal to allow the flow rate pulse from the flow rate transmitter to pass through, and closes based on the gate close signal to output the flow rate pulse. A flow rate correction device comprising: a gate that prevents passage of the flow rate pulse; and an adder that adds the flow rate pulse that has passed through the gate and the pulse signal output from the multiplier.