JPS62298713A - Rotation amount measuring apparatus - Google Patents

Abstract

PURPOSE:To prevent over-counting accompanied by a possible unnecessary vibration, by detecting alternately a specimen upon rotation of a rotating body by each detecting member. CONSTITUTION:When a sudden change of measuring amount causes vibrating rotary motion of a rotating body 1 and change is observed on the specimen 3 in a vibrating stroke by a detecting member 4, the same detecting member 4 detects the same specimen 3 in an overlapping manner. However, as a counting member 5 is so constructed that, it proceeds counting only when a detecting signal from each detecting member 4a, 4b is introduced alternatively; a series 1 of detecting signals detected continuously is subjected to counting only and accordingly, over-counting caused by overlapped detections can be prevented.

Description

[Detailed Description of the Invention] 3. Detailed Description of the Invention (Field of Industrial Application) The present invention relates to a device for measuring the amount of rotation in various measuring instruments in which the measuring lid is taken out as a mechanical rotating lid. be.

(Prior art and its problems) For example, a magnetic coupling is used to transmit rotational force from a positive displacement rotating shaft used for highly accurate measurement of minute flow rates to a rotating body C for measuring the amount of rotation. It is configured to reduce rotational torque. Symbols d and d' are magnets on the main body side and the rotating body side, respectively, which constitute the magnetic coupling.

Then, a magnet e is attached to the rotating body C at each equal rotation angle, and a magnetic sensor f is installed in the vicinity of the rotating body C, and the rotation amount of the rotating body C corresponding to the measurement f-ffi is measured by the magnet em. The measured quantity is determined by counting.

However, due to this small torque,
A vibration system is constructed by the inertia and magnetic force of the rotating body C. Therefore, when the flow of the fluid to be measured is a pulsating flow due to the use of a diaphragm pump, etc., sudden changes in the flow rate of the fluid,
Especially when stopping suddenly, the rotating body may vibrate unnecessarily.
There is a problem in that it overcounts and measures a flow rate higher than the actual flow rate.

The present invention aims to solve the above conventional problems, and will be described in detail below based on drawings corresponding to embodiments.

(Means for Solving the Problems) In FIGS. 1 and 2 corresponding to the embodiment, the reference numeral 1 indicates an appropriate case where the measured amount is taken out as a mechanical rotation amount, such as the above-mentioned positive displacement flowmeter. A rotating body connected to a measuring device and configured to rotate in response to the amount measured by the measuring device,
2 is the rotation axis.

This rotating body 1 has a plurality of detection targets 3 (3, 3, 3,...
) are configured for each equal rotation angle, and a pair of detection units 4 (4a, 4b') for detecting the detection target 3 are configured at positions where the detection phases are opposite to each other. Here, detection target 3
To specifically explain the embodiment of the detection unit 4, the first
In the illustrated embodiment, the detection target 3 is constructed as a light reflecting section, the detection section 4 is constructed as a light transmitting/receiving section, and the detection target 3 is detected by a light reflection method. In addition, in the embodiment shown in FIG. 2, the detection target 3 is constructed as a light transmitting section, and the detecting section 4 includes light transmitting sections 4 installed on both sides of the light transmitting section.
, a light receiving section 4', and detects the detection target 3 in a light transmission manner. In addition, the object to be detected 3 and the detection section 4 may have any suitable configuration, such as a magnetic type as in the conventional example described above, but an optical type has the advantage that the detection range can be narrowed.

Further, the number of detection targets 3 and the installation position of the detection units 4 are also appropriate as long as the detection phases of the pair of detection units 4a and 4b are opposite to each other. Note that reference numeral 14 is a recessed portion for preventing erroneous reflection detection.

Accordingly, the present invention is configured such that the detection signals from the respective detection sections 4a and 4b are input to the counting section 5, and the amount of rotation of the rotating body 1 is measured from the count value.
The counting section 5 is configured to advance the count only when detection signals from the respective detection sections 4a and 4b are alternately inputted. As long as the counting unit 5 has such a function, it can be configured as appropriate in terms of hardware or software in addition to the embodiments described below.

(Function) In the above configuration, when the rotating body 1 rotates in response to the amount measured by the measuring instrument, each of the detection units 4a and 4b detects the detection target 3.
are alternately detected and input to the counting section 5 as a detection signal, and by counting the detection signals in the counting section 5, the amount of rotation of the rotating body 1 can be measured. Then, the measured quantity can be determined based on the correspondence between the amount of rotation of the rotating body 1 and the measured quantity by the measuring instrument.

In the above case, even if the measured quantity does not change suddenly and therefore the rotating body 1 rotates continuously without vibrating, or even if the measured quantity changes suddenly and the rotating body 1 rotates while vibrating. , within the vibration loaf, if the detection state of the detection target 3 by the detection unit 4 does not change, the detection signals from the detection units 4a and 4b alternate as shown in FIG. 3(a). is input to the counting section 5, and the count is advanced. For example, in the case of FIG. 3(a), a count of 6 is made.

However, if the measured quantity suddenly changes and the rotating body 1 rotates while vibrating, and the detection state of the detection target 3 by the detection unit 4 changes within the vibration stroke, the same detection unit 4 The same detection target 3 will be detected redundantly. For example, in FIG. 3(b), before the third detection signal is detected by the detection unit 4a, the measured amount decreases rapidly, and the rotating body 1 vibrates once, for example, and both ends of the vibration stroke end. In this case, if the detection target 3 crosses the detection state position by the detection unit 4a, the detection signal (fourth) in FIG.
As shown in b), the same detection target 3 is detected three times in duplicate. Note that if the detection position is at the end of the vibration stroke, the detection will be performed twice.

However, in the present invention, the counting section 5 is configured to advance the count only when the detection signals from the respective detection sections 4a and 4b are inputted alternately. The detected signal sequence is counted only once, and therefore overcounting due to duplicate detection can be prevented. Note that the above-mentioned compensation cannot be performed when both the detection units 4a and 4b detect the detection target 3 during the vibration stroke, but this can be done by adjusting the angle between the adjacent detection targets 3. It can be easily solved. As described above, in the present invention, the rotating body 1 vibrates and rotates according to the flow rate, as in the case where a minute flow rate of liquid discharged by a diaphragm pump or the like is measured with high accuracy using a volumetric flow rate needle. Even when moving, the amount of rotation can be accurately measured, and thus the measured quantity such as flow rate can be measured with high precision. Incidentally, in the figure, the detection signal is schematically shown as a rectangular wave, and the actual detection signal may be counted after performing desired signal processing such as waveform shaping.

(Structure and operation of the embodiment) As described above, the counting section 5 includes the respective detection sections 4a,
As long as the count is advanced only when the detection signals from 4b are inputted alternately, it is possible to make an appropriate hardware and software configuration, and one embodiment thereof will be described next. That is, the counting section 5 shown in FIG. 4 includes set input sections 7a, 7b and reset input sections 13a, 9b for each input section 13a, 6b corresponding to the pair of detection sections 4a, 4b. Reset circuits 10a, 10b and 2-input AND gate circuits 11a, 11b are provided, which operate at the rising edge of a flip-flop lower circuit 9a*9bs signal, and input portions 5a, 5, respectively.
b to one input part of the AND gate circuits 11a and 11b, and the reset input parts 9a and gb of the flip-flop circuits 9a and 9b via the reset circuits 10a and 10b.
and to the set input sections 7b, 7a of the flip-flop circuits 9b, 9a on the other side, and connect the output sections of the flip-flop circuits 9a, 9b to the AND gate circuit 11a.
, 11b, and OR the outputs of the husband's AND gate circuits 11a and 11b.

This configuration is connected to a counter 13 via a gate circuit 12.

The operation of the above configuration will be explained based on the time chart shown in FIG. Note that delay time is ignored in this time chart. First, when a detection signal is input to the input section 6a, this signal sets the flip-flop circuit 9b on the other side and is input to one input section of the AND gate circuit 11H. Prior to such detection 1 divination symbol, the input unit 6
If a detection signal has been input to b, the flip-flop circuit 9a has been set in advance by the detection signal, so an output corresponding to the detection signal appears at the output section of the AND gate circuit 11H, and the OR gate circuit 12 and is input to the counter 13. Then, when the detection signal of the input section 6a falls, the reset circuit 10a outputs a reset pulse to reset the flip-flop circuit 9a. When the detection signal is input to the input section 6b following the above, similar to the case where the detection signal is input to the input section 6a,
Since the flip-flop circuit 9b is set in advance, an output corresponding to the detection signal appears at the output part of the AND gate circuit 11b, passes through the OR gate circuit 12, is input to the counter 13, and is input to the flip-flop circuit on the other side. 9a is set, and the flip-flop circuit 9b is reset at the fall of the detection signal.

In this way, when the detection signals are alternately input to the input sections (ia, 5b), the output corresponding to each detection signal is inputted to the counter 13 without exception, and the count can be advanced.

However, if the detection signal is input to the input section 6a as described above, and the detection signal No. 18 is input again immediately after it falls, the flip-flop circuit 9a is reset by the fall of the detection signal of Ail. Since it remains as it is, no output appears at the output section of the AND gate circuit 11a, and therefore the counter 13 does not advance the count. In this state in which the detection signal is continuously input to the input section 6a, the other flip-flop circuit 9b is always in the set state, so that when the detection signal is successively input to the input section 6b, the other flip-flop circuit 9b is always set. As described above, the detection signals can be counted without omission by the counter 13.

(Effects of the Invention) As described above, the present invention includes a rotating body that is connected to a measuring device and configured to rotate in accordance with the amount measured by the measuring device, and a plurality of detection targets are configured at equal rotation angles, A pair of detection units for detecting the detection target are configured at positions where their detection phases are opposite to each other, and detection signals from each detection unit are input to a count unit, and the amount of rotation of the rotating body is calculated from the count value. The counting section is configured to advance the count only when the detection signals from the respective detection sections are alternately input, so that the rotating body constitutes a vibration system to prevent sudden changes in the measured quantity. Even if unnecessary vibration occurs due to a change in temperature, overcounting will not occur, and therefore the measured quantity can be measured with high precision.

[Brief explanation of the drawing]

1 and 2 are explanatory diagrams showing the configuration of an embodiment of the present invention,
Figures 3 (a) and (b) are time charts showing the operation, Figure 4 is an example of the counting section, Figure 5 is a time chart showing the operation of Figure 4, and Figure 6 (a) and (b). ) is an explanatory diagram of a conventional example. Symbol 1... Rotating body, 2... Rotating shaft, 3 (3, 3,
3,...) detection target, 4 (48, 4b door...detection unit,
5... Count section % 5a, (ib... Input section s
7 a+ 7 b...Set input section, 8a, 8b...
- Reset input section, 9a. 9b...Flip-flop circuit, IOA, 10b
... Reset circuit, 11a, 11b -A N
D gate circuit, 12... OR gate circuit, 13...
Counter, 14... recess.

Claims (3)

[Claims] (1) A pair of detection systems that detect a plurality of detection targets arranged at equal rotation angles on a rotating body that is connected to a measuring instrument and configured to rotate in accordance with the amount measured by the measuring instrument. the respective detection parts are configured to have opposite phases, and the detection signals from the respective detection parts are input to the counting part to measure the amount of rotation of the rotating body from the count value, and the counting part The rotation amount measuring device is characterized in that the count is advanced only when detection signals from the respective detection sections are inputted alternately. (2) The counting section includes a flip-flop circuit provided with a set input section and a reset input section for each input section corresponding to each of the pair of detection sections, a reset circuit that operates at the falling edge of a signal, and a two-input AND gate. a circuit is provided, the respective inputs being connected to one input of the AND gate circuit, to the reset input of the flip-flop circuit via a reset circuit, and to the set input of the flip-flop circuit on the other side; AN output part of the circuit
Claim 1 characterized in that it is connected to the other input part of the D gate circuit, and the output part of each AND gate circuit is connected to the counter via an OR gate circuit.
Rotation measurement device described in section (3) The rotational amount measuring device according to claim 1, wherein the detection section is configured as a light transmitting/receiving section, and the detection target is configured as a light reflecting or transmitting section.