RU2030713C1 - Electromagnetic flow meter - Google Patents

Abstract

FIELD: measuring equipment. SUBSTANCE: flow meter has one measuring converter 1, one non-conducting passage 2, one magnetic system 2, two pickups 4, one repeater 5, one adder 6, one amplifier of difference signal 7, one source of compensation signal 8, one compensator 9, one interference compensator 10, one generator of reference signal, one amplifier of the reference signal 12, one generator of reference signal 13, and indicator. EFFECT: improved design. cl, dwg

Description

 The invention relates to metrological support for measuring the flow rate of media with ionic conductivity (liquids, solutions, pulps, etc.) in pipelines.

 Known electromagnetic flow meters (flow meters) [1 and 2] include electromagnetic transducers probing the measured flow with an alternating magnetic field. The electromotive force (EMF) arising in this case in a moving medium in accordance with the phenomenon of electromagnetic induction, the magnitude of which is proportional to the flow velocity and magnetic field induction in the transducer channel, is measured by the electronic measuring unit of the flow meter and registered by a corresponding indicator.

 The disadvantage of analogues is the low accuracy of the measurement if the voltage and frequency of the supply network are unstable. This is primarily due to the use of phase shifting devices of RC elements in the feedback circuit.

 As a prototype, an electromagnetic flow meter is selected comprising a flow transducer, a voltage follower, a compensation signal source connected between the output of the follower and the input of the flow transducer, and a measuring circuit connected to the follower's output, a current-voltage converter connected between the follower's output and the first input of the signal source compensation, a two-coordinate control circuit connected between the second output of the current-voltage converter and the second and third inputs of the signal source compensation, while the fourth input and the second two-coordinate control circuitry are interconnected [3].

 The disadvantage of the prototype is the relatively low accuracy of the measurement. This is due to the following disadvantages of the reference signal source of the flow meter: firstly, the use of a winding placed in the magnetic system of the flow transducer as the reference voltage source leads to the fact that this reference voltage displays only some average value of the magnetic field in the channel of the flow transducer. At the same time, it is known that various elementary volumes of the measured medium moving along the transducer channel make a substantially different contribution to the EMF taken from the transducer measuring sensors, i.e. a change in the flow velocity (and hence ultimately the flow rate) in different zones of the transducer channel leads to a change in the signal of the flow transducer and the reference voltage of different magnitude, which leads to significant measurement errors. Obviously, it is more correct to use the voltage generated in the zones where the bulk of the signal of the flow transducer is induced as the reference voltage. Such zones are areas directly adjacent to the sensors of electromagnetic transducers, and secondly, phase-shifting circuits on RC elements provide precision tuning of electronic equipment only in a narrow frequency range, and in this regard, flow meters using such circuits provide the necessary measurement accuracy only for small frequency variations.

 The aim of the invention is to improve the measurement accuracy of electromagnetic flowmeters by reducing the impact on their readings of variations in frequency and voltage. This is extremely relevant, first of all, when using such measuring instruments in conditions when unsteady and mobile low-power electrical installations have to be used as power sources, in which variations in the frequency and voltage of the output signals can reach significant values.

 This goal is achieved due to the fact that in the electromagnetic flow meter containing a flow meter connected to the input of the repeater, the reference signal source connected to the source of the compensation signal, and the meter, the adder and the amplifier of the differential signal are additionally connected in series, while the output of the repeater is connected to the first input of the adder connected by the second and third inputs to the first and second outputs, respectively, the source of the compensation signal connected to the third and third inputs to the output of the difference signal amplifier, and the reference signal source is made in the form of two series-connected reference coils, in addition, the compensation signal source is made in the form of a series-connected reference signal shaper and signal compensator, as well as series-connected reference signal amplifier interference, while the inputs of the driver of the reference signal and the amplifier of the reference signal of the quadrature are combined and connected to the first inputs of the signal compensators interference and interference, the second and third inputs of which are connected to the second inputs of the signal compensators and interference, respectively, whose outputs are connected to the first and second outputs of the compensation signal source.

 The drawing shows a structural diagram of an electromagnetic flow meter.

 An electromagnetic flow meter contains a measuring transducer 1, consisting of a non-conductive channel 2, made in the form of a pipe made of non-magnetic materials (plastic, ceramic, etc.). If the channel 2 is made of electrically conductive material, its inner surface is covered with insulating material (rubber, plastic, etc.) of the magnetic system 3 and sensors 4. The magnetic system consists of two series-connected bushings diametrically placed on the outside of the channel 2, and the magnetic field created by it is perpendicular to the plane connecting the sensors 4. To increase the induction in the meter channel, the excitation coils of the magnetic system 3 can be covered by a magnetic circuit. The sensors 4 are measuring electrodes mounted on channel 2 and mounted flush with the inside of channel 2. The EMF induced in channel 2 from the sensors 4 is fed to the input repeater 5, which is the amplifier of the measuring unit, from the output of the repeater 5, the signal is transmitted to one from the outputs of the adder 6, in which the algebraic summation of the signals supplied to its input is carried out, from the output of the adder 6, the signal goes to the amplifier of the differential signal 7, which is a device, directly but the reinforcing signal applied to its input and converts the signal into a direct current. The output of the difference signal amplifier 7 is connected to the first and second inputs of the compensation signal source 8, including signal compensators 9 and interference (quadrature) 10, as well as a reference signal driver 11 and a quadrature reference signal amplifier 12, and the outputs are connected to the second and third inputs of the adder 6. Signal compensators 9 and interference 10 are devices that prepare signals for suppressing measurement interference: the amplitude and phase of the output signals of these devices are formed depending on the polarity and magnitude of the input apryazheny. The reference signal source 13, containing two series-connected coils (inductive) located at a minimum distance from the sensors 4 and in the plane; orthogonal to the magnetic field of the magnetic system 3, the support coils 13 with the inputs of the driver 11 and the amplifier 12, the outputs of which are connected to the second inputs of the signal compensators 9 and interference 10. The driver 10 is an integrating amplifier, and the amplifier 12 is an AC amplifier. The indicator 14 is connected to the output of the amplifier 7 and is a direct current measuring device, calibrated in units of fluid flow.

 The work of the proposed electromagnetic flow meter is as follows.

 When a medium with ionic conductivity moves along a non-conductive channel 2 in the magnetic field of the magnetic system 3 of the converter, EMF is induced in it. Induced EMF, the value of which is proportional to the average velocity of the medium, and since the cross-sectional area of channel 2 of the flow transducer 1 is known and fixed, proportional to the flow rate, it is taken by means of sensors 4 and fed to the measuring unit. The flowmeter measuring unit is built on the principle of a statistical system of automatic regulation. The signal from the sensors 4 is fed to the input repeater 5, where it is pre-amplified: then to the first input of the adder 6, then to the input of the amplifier 7. The differential signal, which is a measure of flow, is registered by indicator 14. To organize feedback on the flow, part of the voltage from the output the amplifier 7 is fed to the input of the compensator 9, and then to the second input of the adder 6. To reduce the influence of quadrature interference on the results of flow measurements, a compensator 10 is introduced into the measuring unit of the flow meter, controlled by the output signal ilitelya 7.

 The reference voltages are supplied to the compensators 9 and 10 from the support coils 13. These compensators 9 are supplied to the compensator 9 through the former 11, in which the reference signal is amplified and integrated with high accuracy, and the compensator 10 is fed through the amplifier 12. From the compensators 9 and 10, the signals arrive at the second and third inputs of the adder 6. A higher correlation between the fluctuation of the flow rate and the reference voltage in the proposed flow meter is achieved due to the fact that the support coil 13, which is removed from the reference voltage, is placed It is in the regions where the main part is formed by the flow transducer signal. The presence of this higher correlation allows the suppression of quadrature interference with greater efficiency. This is realized by an amplifier 12, where the amplification of the reference voltage and the compensator 10 takes place.

The independence of the readings of the flow meter from variations in the frequency and supply voltage is due to the fact that a phase shift of 90 ^{° of the} reference voltage is carried out by integrating it in the driver 11. In this case, when the frequency and voltage of the supply network change, the signal taken from the sensors 4 of the converter and the integrated the reference voltage in the reference voltage driver 11, used as a compensating feedback voltage, will change according to one law, which makes the quadrature compensation process th interference beyond the control of the frequency and measuring the supply voltage.

 The latter is confirmed by the following calculations.

The change in the readings of the proposed electromagnetic flow meter - the change in the readings of the indicator 14, which records the flow, comes when the differential signal And, which is a measure of the flow and represents the difference between the signal E, taken from the sensors of the flow transducer and the feedback signal And _OS , i.e.

Q (2) где J₁-J₂ - разность потенциалов, снимаемая с датчиков 4 преобразователя расхода,
К - безразмерный коэффициент, зависящий от геометрических и конструктивных параметров преобразователя расхода и определяемый при градуировке расходомера,
В - индукция магнитного поля в канале преобразователя расхода;
L и S - расстояние между электродами и площадь поперечного сечения канала преобразователя расхода соответственно;
V и Q = V˙S - скорость и объемный расход измеряемой среды.U _o = E - U _OS (1)
The signal taken from the sensors 4 of the transducer of the electromagnetic meter of the flow of media with ionic conductivity is determined as follows:
E = J ₁ -J ₂ = KBLV =

Q (2) where J ₁ -J ₂ is the potential difference taken from the sensors 4 of the flow transducer,
K is a dimensionless coefficient depending on the geometric and structural parameters of the flow transducer and determined during the calibration of the flow meter,
B — magnetic field induction in the channel of the flow transducer;
L and S are the distance between the electrodes and the cross-sectional area of the channel of the flow transducer, respectively;
V and Q = V˙S are the velocity and volumetric flow rate of the measured medium.

, (4) cоздавая в непроводящем канале 2 преобразователя расхода магнитное поле с индукцией
B =

, (5) где U_o и ω- амплитуда и частота сети питания расходомера;
W - количество витков в обмотке магнитной системы 3 преобразователя;
S* - площадь сечения магнитной системы 3 преобразователя расхода.Since the magnetic system of the flow converter is powered by AC power
U = U _o ˙sinωt, (3) then the applied voltage is balanced by the EMF of self-induction in the winding of the magnetic system 3
U = -e = - WS *

, (4) creating a magnetic field with induction in a non-conducting channel 2 of the flow transducer
B =

, (5) where U _o and ω are the amplitude and frequency of the power supply network of the flowmeter;
W is the number of turns in the winding of the magnetic system 3 of the Converter;
S * is the cross-sectional area of the magnetic system 3 of the flow transducer.

, (6) где K₁ = KL/W˙S˙S* - постоянный для конкретного преобразователя расхода коэффициент.In accordance with the obtained relation (5), the signal recorded from the sensors 3 of the flow transducer (2) can be determined as follows:
E = K ₁

, (6) where K ₁ = KL / W˙S˙S * is a constant coefficient for a specific flow converter.

The feedback signal U _{OS is} proportional to the value of the reference voltage U _sm and the differential voltage, which in turn is also proportional to the flow rate, i.e.

U _oc = K ₂ ˙Q˙U _receptacle (7) where K ₂ - the gain of the differential signal amplifier.

, (9) где К₃ - постоянный для конкретного расходомера коэффициент, определяемый количеством витков, площадью и местом размещения катушек 13;
К₄ - коэффициент усиления формирователя опорного сигнала 11.The reference voltage is selected by the source of the reference voltage, consisting of reference coils 13 located in the field of the magnetic system 3 of the transducer, powered by an alternating current main and introduced into the measuring unit of the flowmeter of the driver of the reference signal P. In this case, the signal taken from the reference coils 13 and fed to the driver reference signal 11
U _cat = K ₃ ˙U _o ˙sinωt, (8) is subjected to integration there with high accuracy, whereby it takes the following form:
U _zn = K ₄ · K ₃ ·

, (9) where K ₃ is a constant constant for a particular flowmeter, determined by the number of turns, the area and location of the coils 13;
To ₄ is the gain of the driver of the reference signal 11.

·Q , (10) где К₅ = К₂˙К₃˙К₄
Полученные результаты (6) и (10) показывают, что сигнал измерительного преобразователя и проинтегрированное задающее напряжение в предложенном электромагнитном измерителе расхода изменяются по одному закону.In accordance with (9), the feedback signal (7) can be represented as
U _OS = K ₅

· Q, (10) where К ₅ = К ₂ ˙К ₃ ˙К ₄
The results obtained (6) and (10) show that the signal of the measuring transducer and the integrated reference voltage in the proposed electromagnetic flow meter change according to one law.

 Thus, due to the use of two serially connected support coils placed in a magnetic field at a minimum distance from the sensors 4 in a plane orthogonal to the magnetic field as a source of the reference signal, and the introduction of the driver of the reference signal 11, which is a high-precision integrating amplifier of the reference signal, in the measuring unit and the amplifier of the reference signal of the quadrature 12, provides a large correlation between the fluctuations of the flow rate and the reference voltage, as well as the identical phase -frequency characteristic of the compensating signal and the transducer signal while changing the frequency and voltage meter, thus reducing its dependence on indications of instability of frequency and voltage, i.e. improve measurement accuracy.

Claims (2)

 1. ELECTROMAGNETIC FLOW METER, comprising a flow meter connected to the input of the repeater, a reference signal connected to the source of the compensation signal and a meter, characterized in that a series-connected adder and amplifier of the differential signal are introduced into it, while the output of the repeater is connected to the first input the adder connected by the second and third inputs to the first and second outputs, respectively, the source of the compensation signal connected by the second and third inputs to the output amplifies A difference signal and the reference source is in the form of two series-connected coils support.  2. The flow meter according to claim 1, characterized in that the source of the compensation signal is made in the form of series-connected reference signal shaper and signal compensator, as well as series-connected reference signal amplifier quadrature and noise canceller, while the inputs of the reference signal shaper and reference signal amplifier are combined and connected to the first input of the compensation signal source, the second and third inputs of which are connected to the second inputs of the signal compensator and the interference compensator, respectively, the outputs which are connected to the first and second outputs of the compensation signal source.