LT4189B - Electromagnetic flowmeter - Google Patents

Abstract

The invention is intended for a flowing liquid debit and the quantity measurement by an electromagnetic method, using a lower frequency pulse magnetic field. In order to simplify the structure of the electromagnetic debit measuring device and increase the precision of measurement there is a transducer installed (1), consisting of a non-magnetic material tube (2) with two inside electrodes insulated from the tube walls and a electromagnet, containing the first (3) and second (4) excitation windings. The amplifier (5) is connected to the transducer (1) by the first and second inputs of the electrodes. Also connected are; an excitation current generator (9), a demodulator (6), a control pulse generator (8), integrator (10), normative unit (7), consisting of an analogue-digital converter (17), and a division block (18) and an indication unit (16), additionally including dual diode stabilitron (15) and the first (11), second (13) and third (12) keys.

Description

The invention relates to the measurement of the flow and volume of fluids by electromagnetic means using a low frequency pulsed magnetic field.

Known electromagnetic flowmeter with sensor, excitation current generator and transducer signal transducer. The transducer consists of a non-magnetic tube section with an internal insulating surface with electrodes and overhead magnetic field excitation and induction coils. It adjusts the magnitude of the excitation current depending on the magnitude of the signal received in the induction measuring coil so that the magnetic field induction value is constant. Such a flowmeter greatly reduces the influence of the magnetic circuit parameters of the sensor on the accuracy of the flowmeter measurement [European Patent EP 0 521 699, G01F1 / 60,1993].

The prototype of the present invention is an electromagnetic flowmeter consisting of a transducer, an excitation current generator, an amplifier, an indication unit, a demodulator, a reference signal detector, an integrator, an analog-to-digital converter, a digital-to-analog converter and a splitting unit. The transducer consists of a section of pipe with insulated electrodes on opposite walls, an electromagnet with two excitation coils, between which is a transducer tube and a support signal windings arranged between the poles of the electromagnet and the pipe. The transducer electrodes are connected to the amplifier inputs and the output is connected via a demodulator to the first input of the splitter unit. The output of the excitation current generator is connected to a series of excitation coils, and the series-connected support signal windings are connected to the input of an integrator, the output of a lair is connected to the input of an analog-to-digital converter. The output of the latter is connected to the input of the second division block, the output of which is connected to the display unit. An analog-to-digital converter with a dividing unit forms a rationing unit that maintains a uniform flowmeter transducer coefficient as the magnetic properties of the electromagnet change. Compared to the analogue described above, this debutenLT 4189 B

It is simpler and consumes less electricity because the magnitude of the excitation current is not adjustable [USSR Patent No. 1S30135, G01F 1 / 58,1991].

However, such a flowmeter has major drawbacks. It is complicated by the need for two additional coils, which are non-technological elements of electrical circuits. These coils should be mounted between the excitation coil and the sensor tube, which adds to the complexity of the sensor design and complicates its assembly. In addition, it practically does not reduce the potential error due to the deposition of ferromagnetic material on the inner wall of the sensor tube, and in the case of a pipeline incorporating a flowmeter in steel, such precipitation will inevitably occur over time. They distort the magnetic field in the active area of the transducer and cause additional error.

The object of the present invention is to simplify the design of the electromagnetic flowmeter and to increase the accuracy of measurement.

This object is achieved by the present invention as follows. In an electromagnetic flowmeter comprising a sensor consisting of a tube of non-magnetic material having two electrodes insulated from the tube wall and an amplifier connected to the first and second input windings of the electromagnet, the excitation current generator, the demodulator, a generator, an integrator, a rationing block consisting of an analogue-to-digital converter ii dividing block, the first input of the first excitation coil being connected to a first output integrator output of the excitation current generator coupled to a second signaling input of the rationing unit; , and the control input with the seventh output of the master pulse generator, the first output of which is coupled to the excitation current generator, the second, third and fourth the second outputs with the integrator's first, second and third control inputs, and the fifth and sixth outputs with the first and second demodulator control inputs, respectively,

The signal input of which is connected to the output of the amplifier and the analog input of the dividing unit is the first input of the normalization unit, its second input is the input of the analog to digital converter and the output of the latter is connected to the digital input of the dividing unit , a two-way voltage limiter consisting of a resistor and a two-way diode stabilizer, and the first, second and third keys, the first and second key signal inputs connected to the second output of the excitation current generator, the first key signal output to the second outputs of the second excitation coil, and - via the resistor, with the second input of the integrator, and connecting the second outputs of the first excitation coil and the first outputs of the second excitation coil to the signal output of the second key and the first input of the integrator, in addition. at the first and second integrator inputs, the third key signal input is connected to the output of the rationing unit,. the signal output is to the indication unit input, the first and third key control inputs are connected to the eighth, o. the second with the ninth output of the master pulse generator.

The electromagnetic flowmeter proposed by the authors is simpler because it does not contain additional coils which are difficult to manufacture and difficult to install. The change of the magnetic field in the active zone of the sensor can also be measured by measuring the mutual inductance between both excitation coils, which is done in the proposed flowmeter. Because the excitation coils are on different sides of the transducer tube, the measurement of the mutual inductance between the two excitation coils more accurately reflects the change in magnetic field inside the tube than the mutual inductance between the excitation coil and the reference voltage coil on one side of the tube. In addition, the mutual inductance between the excitation coil and the reference voltage coil, and thus this mutual inductance EVJ, is virtually insensitive to magnetic field.

-4k distortion due to ferromagnetic sediment on the tube walls. In the present invention, the EVJ of the mutual inductance between the two excitation coils is sensitive to such precipitation, which makes it possible to avoid measurement error for this reason. Measurement accuracy increases. The whole set of elements of the present invention is unknown to the authors, so it can be said that the technical solution is new and meets the requirements of the invention.

A block diagram of the proposed electromagnetic flowmeter is shown in Figure 1. . The electric magnetic flowmeter has a sensor 1 consisting of a tube 2 with electrodes and an excitation coil of the first and second 4. The first and second inputs of the amplifier 5 are connected to the transducer electrodes, and the output is to the input of the deck dimmer 6 whose output is connected to the first signal input of the rationing unit 7 and the first and second control inputs to the fifth and sixth outputs of the control pulse generator 8, respectively. the first output of which is connected to the input of the excitation current generator 9, the second, third and fourth outputs of the integrator 10, respectively, the first, second and third control inputs, the seventh output to the control input 7, the eighth output to the first 11 and a third 12-key control inputs, and a ninth output with a second 13-key control input. The first output of the first excitation coil 3 is coupled to the first output of the excitation current generator 9, the second output to the first output of the second excitation coil 4, the first input of the integrator 10, and the second output 13 to the second output of the generator 9 which connected to a second output of the second excitation coil 4 and - via a resistor 14 - to a second input of the integrator 10, the output of which is coupled to the second signal input of the normalization block 7, and a duplex diode stabilizer 15 between the first and second integrator inputs. which is connected via the third key 12 to the input 4189 B of the indicating unit 16

- 3 mu, is comprised of an analog-to-digital converter 17 and a division unit 1S. The input of the transducer 17 is simultaneously the second signal input of the rationing unit 7 and the analog input of the dividing unit 18 is the first signal input of the rationing unit 7. The output of the converter 17 is coupled to the digital input 1S of the splitter block, the output of which is simultaneously the output of the rationing unit 7. The torque 14 and the double-sided diode stabilizer 15 form a two-way voltage limiter 19.

. The flowmeter has two operating modes: calibration and measurement. In the calibration mode, the eighth output of generator 8 generates a pulse disconnecting the first 11 and third 12 keys, and the ninth output of the S generator generates a pulse connecting the second key 13. At the beginning of this mode, followed by a pulse output from the third output of the third generator 8 to the second input of the integrator 10, recording the voltage value at the output of the integrator before the start of the integration Ujo. Thereafter, a pulse is formed at the first output of generator 8, which starts generating an excitation current pulse of known amplitude I _{o in the} excitation current generator 9. Due to the inductance of the coil, the current does not immediately reach the settled value I _o . As the current changes in the first excitation coil 3, the second excitation coil 4 induces EVJ E ^ proportional to the rate of change of the magnetic field induction B _{2 in the} second coil, and the value of induction B2 is proportional to the value of induction B in the active sensor area.

dB

So E _m - KN, S -, where N ₂ - number of turns of the second excitation coil, S - dt of its turns

B is the average area, K = - proportionality factor. In the integrator 10 irttegB 2, we keep this voltage up until the excitation current flows (and stops B). At its output we get the voltage Ui = KoB + Uj _a , here - Kc — KEBS, U U ~ - the voltage formerly integratedLT 4189 B

-6or the output before the voltage E _M integration begins. The integrator is used here in the same way as [2] and has a subtraction unit providing a reference voltage Uo = Ui - U _io = KoBo. When this voltage occurs at the output of the integrator, a start pulse is applied from the seventh output of the generator 8 to the control input of the analog-to-digital converter 15 and the output No of the converter 15 is proportional to the voltage Uo and thus induction B in the active sensor.

When the number No is formed, the first keys 11 and the third 12 are combined, and the second key 13 is disconnected and the flowmeter starts operating. The flowmeter operates in the same mode as the flowmeter described in [2]. When a pulse S is applied at the first output of the generator, a rectangular current pulse of that duration is produced at the output of the generator 6. The signal at the amplifier output 5 is proportional to the voltage between the sensor electrodes. 6 demodulators impulse fifth eight generator output remembers five amplifier output voltage _Uo when the sensor is no magnetic field, and the impulse sixth eight generator output remembers five amplifier output voltage U _of the sensor is affected by magnetic field and the excitation current transition has expired . The demodulator output voltage Ug equals the difference between these two voltages. It is proportional to the fluid flow rate: U6 = U _m -Uo = = KgBQ. HereKg = const. In block 18, this voltage is divided by the number No generated at inverter output 17 during calibration mode. At the output of block 18 we obtain a voltage Uia independent of the magnetic field induction in the active area of the daK motor: U, _s = K _{JS —-} Q = K “Q. HereKig = const, Ko == KigK6 / Ki = const. This ^K i voltage is supplied to the display unit 16.14 by a resistor and a 15-sided diode stabilizer 15 to limit the voltage at the output of the integrator 10 in operating mode.

-7Depending on the sensor operating conditions, the calibration mode may be repeated each time the voltage is measured or after a certain time.

In the output proportional to the output of block 18 of the signal, the invariance with respect to the magnitude of the magnetic field induction is obtained by simpler means than in the prototype. In addition, this invariance is maintained if ferromagnetic deposits appear on the inside walls of the sensor. This increases the accuracy of the measurement. This is especially true if the magnetic field excitation coils do not have a core, because then the ferromagnetic sediment more distorts the magnetic field in the active sensor area.

-Definition of Invention

Claims (1)

Definition of the Invention Electromagnetic flowmeter comprising a sensor consisting of a tube of non-magnetic material containing two electrodes insulated from the tube wall and an amplifier, an excitation current generator, a demodulator, connected to the first and second inputs of the sensor electrodes with a first second input a generator, an integrator, a normalization unit and an indicator unit consisting of an analog-to-digital converter and a dividing unit, the first input of the first excitation coil being connected to the first output of the excitation current generator, the output of the integrator being connected to the second signal input connected to the output of the demodulator and the control input to the seventh output of the control pulse generator, the first output of which is coupled to the input of the excitation current generator, the second, third and the fourth outputs with the first, second and third control inputs of the integrator, respectively, and the fifth and sixth outputs with the first and second demodulator control inputs, respectively, of which the signal input is connected to the amplifier output and the second input is simultaneously an analog-to-digital converter input, and the latter output is coupled to a divider block digital input, the output of which is a normalization unit output, in which a two-way voltage limiter consisting of a resistor and a two-sided diode stabilizer , second and third keys, the first and second key signal inputs connected to the second output of the excitation current generator, the first key signal output to the second outputs of the second excitation coil and via the resistor to the integrator on the and the first excitation coils onLT 4189 B -9 to connect the second terminals and the first terminals of the second excitation coil to the second key signal output and the integrator's first input, in addition, a duplex diode stabilizer is connected between the first and second integrator inputs, the third key signal input is connected to the normalization block output Input, the first and third key control inputs are connected to the eighth and the second to the ninth master pulse outputs.