FR2509853A1 - Fault monitor for fluid flowmeter - produces pulses from rising and falling edges of two pulse trains produced from respective detectors of motion of cog wheel - Google Patents

Abstract

The device contains two pulse converting units. Each unit contains two pulse generators (1,2,3,4). Two detectors associated with a toothed wheel, driven by the rotary measuring apparatus, and emit two chains of square signals (A,B). At each transit on rising and falling edge, the pulse converting units generate two pulse trains (a,b) from the square signals (A,B). A device verifies the alternance of these pulse trains (a,b) so that any transmission fault is detected. The device can detect an inversion of the rotation direction of the meter during measurement as well as faults such as e.g. a cut wire, interference etc.

Description

Control device in operation of a rotary measuring device.

 The subject of the present invention is a device for checking the operation of a rotary measuring device, making it possible to obtain the simultaneous detection of two operating faults, namely the failure of a component, the cutting of a transmission wire. , parasitic effects and the like, ie an inversion, during counting, of the direction of rotation of the counter.

 Up to now, the devices for monitoring rotary measurement devices, using the detection of anomalies in the transmission of counting pulse generated from a toothed wheel, have not made it possible to simultaneously detect the two operating faults. mentioned c1 above.

 The invention relates more precisely to a control device in operation of a rotary measuring device, for example a fluid flow meter, characterized in that it comprises two pulse conversion units, each consisting of two pulse generators and allowing, on each transit on rising edge and falling edge, from two chains of square signals from two detector devices associated with a toothed wheel driven by the rotary measuring device, to generate respectively two pulse trains, and an alternation control device for these pulse trains intended to detect any transmission anomaly.

 In the control device according to the present invention, each pulse generator generating positive pulses is associated with a logic gate OR ensuring the recombination of these pulses to obtain trains of pulses. Furthermore, the alternation control device comprises a set of AND and OR gates associated with memory means advantageously constituted by flip-flops. This control device furthermore comprises synchronization means constituted by an OR logic gate intended to combine signals leaving the generators to pass them by means giving them a slight delay before transmitting them to one of the memorizing means.

The invention will be better understood on reading the following description of a non-limiting embodiment of devices for controlling anomalies in the transmission of counting pulses from a rotary measuring device, with reference to the appended drawing in which
fig. 1 is a diagram of the various signal trains sent in normal operation of the rotary measuring device;
fig. 2 is a schematic view of the signal trains emitted in disturbed operation, by an internal failure, of the rotary measurement device;
fig. 3 is a schematic view of the signal trains emitted in disturbed operation of the rotary measuring device when a rotation reversal occurs;
fig. 4 is a more detailed schematic view of the alternation control device;
fig. 6, 7, 8 and 9 are operating diagrams of the alternation control device of FIG. 5.

 As shown in fig. 1, in normal operation, the signal trains A and B emitted by a double detection chain placed on a toothed wheel, not shown in the drawing, give rise after passing through the pulse generating units to trains of normal impulses a, b. In the event of disturbed transmission, as shown in fig. 2 (loss of pulse due to internal failure) or fig. 3 (reversal of the direction of rotation), the regular alternation of the pulses disappears on channels a and b, and at least two consecutive pulses occur on the same channel a or b, as indicated by the respective arrows fl and f2. The principle according to the invention therefore consists in carrying out an alternation check on the signals a and b to detect any transmission anomaly.

In the embodiment of FIG. 4, the signals A and B each attack two pulse generators (1, 2; 3, 4), one working on a rising edge and the other on a falling edge, after which two logic gates OR 12 are provided; 13 allowing these signals to be combined to generate the pulse trains a and b. The altance control device, which will be described more precisely in the following, receives the signals a and b in the event of disturbance of the original square signal trains A, B, the output goes from zero to an ei after passing through an inverter 9, blocks the controlled impulse output "by going through a door beforehand
AND 10. The device also includes zero reset means Ro and will remain blocked as long as said reset means have not been actuated.

 As shown in fig. 5, the alternation control device comprises two memorizing means 6 and 7, constituted respectively by two flip-flops which are reset when the device is rearmed. On arrival of the first pulse a or b, the flip-flop 7 will be mounted 1 and will remain there as long as no anomaly appears in the pulse trains it receives. The flip-flop 6 on its side will go to one for each arrival of a pulse b and to zero for each arrival of a pulse a.

There is also a set of AND logic gates 14, 15 16, 17 and OR 19 intended to compare the state of the output of the flip-flop 6 with the signals a and b, so as to detect any anomalies, namely the arrival of a pulse a while the flip-flop 6 is already at zero, or the arrival of a pulse b when this flip-flop 6 is already 1.

 If such an anomaly appears, this comparison stage will reset the flip-flop 2, which will in turn force the flip-flop 1 to 1. The two flip-flops then remain locked in this state until reset by the reset means d zero Ro.

 The fault output D then appears as the logical AND 21 of the direct output Q1 of the flip-flop 6 and of the inverted output Q2 of the flip-flop 2. The whole of this device is synchronized by a clock signal obtained by the combination of the signals a and b by an OR gate 20, after which the combined signal trains are passed through delay means 8 to give them a delay t over H and avoid operational hazards.

 Fig. 6 shows the different states of the signal trains in the alternation control device, in normal operation according to gl of the measuring device to be checked, after pulse start on a. Fig. 7 shows the same signals also in normal operation according to g2 but after pulse start on b. Fig. 8 represents the same signals in the case where two close pulses occur on a, according to arrow f3, which indicates a disturbance in the operation of the measuring apparatus.

 Fig. 9 illustrates the signals in question, when two close pulses occur, according to arrow 4, in the pulse train b, which illustrates the appearance of a disturbance in the measuring device to be checked.

 It is obvious that the invention is in no way limited to the embodiment described above with reference to the appended drawing, but that it also encompasses all the modifications and variants resulting from the same basic principle, namely the implementation work of a double transmission chain to detect both transmission errors and reversals of direction of rotation of the transmitting member associated with the rotary measuring device to be checked.

Claims (5)

 1. Control device for a rotary measuring device, for example a fluid flow meter, characterized in that it comprises two pulse conversion units, each consisting of two pulse generators (1, 2; 3,4) and allowing, with each transit on rising and falling edges, from two chains of square signals (A, B) coming from two detector devices associated with a toothed wheel driven by the rotary measuring device , respectively generate two pulse trains (a; b), and an alternation control device (5) d these pulse trains, intended to detect any transmission anomaly  2. Control device according to claim 1, characterized in that each pulse generator (1, 2; 3,4) generating positive pulses is associated with an OR logic gate (12; 13) ensuring the recombination of the pulses to obtain two pulse trains (a; b), respectively.  3. Control device according to claim l, characterized in that the alternation control device comprises a set of AND logic gates (14, 15; 16, 17) and OR (19) intended to compare the state of output of a flip-flop (6) and which in the event of an anomaly ensures the blocking of this first flip-flop (6) followed by that of a second flip-flop (7).  4. Control device according to claim 3, characterized in that the alternation control device comprises synchronization means constituted by an OR logic gate (20) intended to combine the signals (a, b) to pass them by delaying means (8) giving them a slight delay before passing through the flip-flops (6) and (7).  5. Control device according to claim 1, characterized in that there are provided reversing means (9) cooperating with an AND gate (10) to allow the output of the controlled pulses.