SU553456A1 - Single channel ultrasonic flow meter - Google Patents

Description

one

The invention relates to flow meters and can be used in the design of precision flow meters.

Known single-channel ultrasonic flow meters built on the phase of the pulse-time or pulse-frequency circuits. The latter have the highest measurement accuracy among single-channel ultrasonic flow meters.

A single-channel ultrasonic flow meter is also known, which contains two sync-ring circuits, each of which contains a generator, as well as a series-connected amplifier and photo output capacitor connected to the converter, and a frequency meter connected to one of the counting trigger outputs. The disadvantage of such a flow meter is the presence of an error due to the difference in the magnitude of the ratio of the time shift of the sequence of pulses that is carried out on each sync-ring circuit by different oscillators.

The purpose of the invention is to improve measurement accuracy. This is achieved by the fact that in each synchroset circuit, the flow meter contains a inhibitor circuit and four coincidence circuits, as well as one-stroke and shift trigger common for two circuits, 11: 1111 trigger trigger, two coincidence circuits, two

Claims (3)

,; a quad and two indicators connected in such a way that the inputs of the one-shot are connected to the outputs of two coincident circuits, the input of each of which is connected to different outputs of the counting trigger, the output of the corresponding driver and the output of the shift trigger, the output of the one-shot is connected to one of the inputs of the shift trigger and through the coincidence circuits respectively with the inputs of the generators, the other inputs of each of these coincidence circuits are connected to different inputs of the account trigger, the input of each prohibition circuit is connected to the output of the corresponding circuit Adeni, one input of each of which is connected to the output of the shift trigger, and the other with the corresponding output of the counting trigger, the other input of the shift trigger is parallel to the counting trigger input, these inputs are connected to the outputs of the two coincidence circuits, the other outputs of which are connected to different inputs of the direction trigger and the inputs are from the generator output of one and the former of the other sync ring circuit, the other output of the counting trigger is connected to input1 and two coincidence circuits, the outputs of each of which are connected to the meter and the indicator, and the other inputs These coincidence circuits are connected to different griggs 1a nanowire outs. The drawing shows a functional diagram of the proposed flow meter. The flow meter consists of acoustic transducer 1 with piezoelectric elements 2 and 3, pulse amplifiers 4 and S, drivers 6 and 7, prohibition circuits 8 and 9, generators 10 and 11, coincidence circuits (logic circuit I) 12-21, counting trigger 22, frequency meter 23 of the pulse counters 24 and 25, the one-shot 26, the shift trigger 27, the indicators 28 and 29, and the direction trigger 30. The flow meter operates as follows. The pulse from the generator 10 is fed to the piezoelectric 2. Piezoelectric element 2 emits an ultrasonic pulse against the flow at an angle a to the axis of the transducer. Passing through the medium being measured, the ultrasonic pulse arrives at the piezoelectric element 3. The pulse received by the piezoelectric element 3 is amplified by the amplifier of the pulses 4, formed by the irradiator 6 into a rectangular impulse of duration Tf. The leading edge of the pulse of the former 6 is triggered by the inhibitor circuit 8 and the generator 10 is started. Then the process is repeated. The shift trigger 27 is in such a state that there is no signal-j at the outputs of the coincidence circuits 12 and 13. The frequency of the pulse generator 10 is 51-n ot (C.-V total (.) Where TI is the pulse period of the generator 10; D is the internal diameter of the acoustic transducer; V is the flow rate; C is the ultrasound speed in the measured medium. The pulse from the generator 11 is fed to the piezoelectric element 3. Piezoelectric element 3 emits an ultrasonic pulse downstream at an angle a to the axis of the transducer. The pulse received by the piezoelectric element 2 is amplified by the amplifier 5, formed by the shaper 7 into a rectangular pulse of duration G. The leading edge of the pulse of the former 7 through the prohibition 9 starts the generator P. Then the process repeats. The shift trigger 27 is in such a state that there are no signals at the outputs of the coincidence circuits 19 and 20. The pulse frequency of the generator 11 is expressed as ISinoL C -V-CoSol) .., where T 2 is the period of the next pulse of the generator 11. Once the frequency of the frequencies is D f f j, -. (si-n 2o (, / D) -V is proportional to (3) the flow rate, and therefore to the flow rate. If the generator pulse 10 (or I) coincides with the generator 7 (or 16) pulse at the output of the coincidence circuit 17 (or 15 ) an impulse is formed, which throws the trigger 22 of the counting mode, operates in the setting mode the shift trigger 27 and the direction trigger 30. Then the trigger 27 is shifted to such a state that depending on the state of the count trigger 22 at the output of the coincidence circuit 13 (or 20) a signal is formed, a closing prohibition pattern (or 9), and the coincidence circuit 12 (or 19) passes the signal of the imaging unit 6 (or 7) to the input of the one-shot 26. The falling edge of the pulse of the single-oscillator 26, which has duration C, returns to its initial position the shift trigger 27, is triggered through the coincidence circuit 14 ( or 21) generator 10 (or I). I The period of the pulses of the trigger of the count 22, defined by the moments of coincidence of the pulses of the generator 10 (or 11) with the pulses of the generator 7 (or 6), can be expressed (T1-OTZ + T, where n - the number of complete periods Tj. TI (or T, TI) for the period T. From expression (4) it follows that 1 + DG Since, then T l i (6). The frequency F of the following pulses of the trigger of the count 22, proportional to the flow rate, is measured by the frequency meter 23. When measuring the forward (or reverse) flow direction, the pulses formed at the output of the coincidence circuit 15 (or 17) set the trigger of direction directions 30 in the position where the trigger pulses The counts 22 through the coincidence circuit 16 (or 18) are fed to the forward 28 indicator (or 29) flow direction, as well as to the pulse counter 24 (or 25). Measured by a pulse counter 24 (or 25) the number K «i; / T of the pulses of the trigger of the count 22 is proportional to the amount of liquid that passed through the converter 1 during the time t in the forward (or reverse) direction. Claims of the Invention A single-channel ultrasonic flowmeter containing two sync-ring circuits, each of which contains a generator, as well as series-connected amplifier and driver connected to the converter, and a frequency meter connected to one of the counting trigger outputs, in order to increase measurements In each syncro-ring scheme, the ashodometer contains a prohibition scheme and four schemes